(function (global, factory) {
	typeof exports === 'object' && typeof module !== 'undefined' ? module.exports = factory() :
	typeof define === 'function' && define.amd ? define(factory) :
	(global.proj4 = factory());
}(this, (function () { 'use strict';

	var globals = function(defs) {
	  defs('EPSG:4326', "+title=WGS 84 (long/lat) +proj=longlat +ellps=WGS84 +datum=WGS84 +units=degrees");
	  defs('EPSG:4269', "+title=NAD83 (long/lat) +proj=longlat +a=6378137.0 +b=6356752.31414036 +ellps=GRS80 +datum=NAD83 +units=degrees");
	  defs('EPSG:3857', "+title=WGS 84 / Pseudo-Mercator +proj=merc +a=6378137 +b=6378137 +lat_ts=0.0 +lon_0=0.0 +x_0=0.0 +y_0=0 +k=1.0 +units=m +nadgrids=@null +no_defs");

	  defs.WGS84 = defs['EPSG:4326'];
	  defs['EPSG:3785'] = defs['EPSG:3857']; // maintain backward compat, official code is 3857
	  defs.GOOGLE = defs['EPSG:3857'];
	  defs['EPSG:900913'] = defs['EPSG:3857'];
	  defs['EPSG:102113'] = defs['EPSG:3857'];
	};

	var PJD_3PARAM = 1;
	var PJD_7PARAM = 2;
	var PJD_WGS84 = 4; // WGS84 or equivalent
	var PJD_NODATUM = 5; // WGS84 or equivalent
	var SEC_TO_RAD = 4.84813681109535993589914102357e-6;
	var HALF_PI = Math.PI/2;
	// ellipoid pj_set_ell.c
	var SIXTH = 0.1666666666666666667;
	/* 1/6 */
	var RA4 = 0.04722222222222222222;
	/* 17/360 */
	var RA6 = 0.02215608465608465608;
	var EPSLN = 1.0e-10;
	// you'd think you could use Number.EPSILON above but that makes
	// Mollweide get into an infinate loop.

	var D2R = 0.01745329251994329577;
	var R2D = 57.29577951308232088;
	var FORTPI = Math.PI/4;
	var TWO_PI = Math.PI * 2;
	// SPI is slightly greater than Math.PI, so values that exceed the -180..180
	// degree range by a tiny amount don't get wrapped. This prevents points that
	// have drifted from their original location along the 180th meridian (due to
	// floating point error) from changing their sign.
	var SPI = 3.14159265359;

	var exports$1 = {};
	exports$1.greenwich = 0.0; //"0dE",
	exports$1.lisbon = -9.131906111111; //"9d07'54.862\"W",
	exports$1.paris = 2.337229166667; //"2d20'14.025\"E",
	exports$1.bogota = -74.080916666667; //"74d04'51.3\"W",
	exports$1.madrid = -3.687938888889; //"3d41'16.58\"W",
	exports$1.rome = 12.452333333333; //"12d27'8.4\"E",
	exports$1.bern = 7.439583333333; //"7d26'22.5\"E",
	exports$1.jakarta = 106.807719444444; //"106d48'27.79\"E",
	exports$1.ferro = -17.666666666667; //"17d40'W",
	exports$1.brussels = 4.367975; //"4d22'4.71\"E",
	exports$1.stockholm = 18.058277777778; //"18d3'29.8\"E",
	exports$1.athens = 23.7163375; //"23d42'58.815\"E",
	exports$1.oslo = 10.722916666667; //"10d43'22.5\"E"

	var units = {
	  ft: {to_meter: 0.3048},
	  'us-ft': {to_meter: 1200 / 3937}
	};

	var ignoredChar = /[\s_\-\/\(\)]/g;
	function match(obj, key) {
	  if (obj[key]) {
	    return obj[key];
	  }
	  var keys = Object.keys(obj);
	  var lkey = key.toLowerCase().replace(ignoredChar, '');
	  var i = -1;
	  var testkey, processedKey;
	  while (++i < keys.length) {
	    testkey = keys[i];
	    processedKey = testkey.toLowerCase().replace(ignoredChar, '');
	    if (processedKey === lkey) {
	      return obj[testkey];
	    }
	  }
	}

	var parseProj = function(defData) {
	  var self = {};
	  var paramObj = defData.split('+').map(function(v) {
	    return v.trim();
	  }).filter(function(a) {
	    return a;
	  }).reduce(function(p, a) {
	    var split = a.split('=');
	    split.push(true);
	    p[split[0].toLowerCase()] = split[1];
	    return p;
	  }, {});
	  var paramName, paramVal, paramOutname;
	  var params = {
	    proj: 'projName',
	    datum: 'datumCode',
	    rf: function(v) {
	      self.rf = parseFloat(v);
	    },
	    lat_0: function(v) {
	      self.lat0 = v * D2R;
	    },
	    lat_1: function(v) {
	      self.lat1 = v * D2R;
	    },
	    lat_2: function(v) {
	      self.lat2 = v * D2R;
	    },
	    lat_ts: function(v) {
	      self.lat_ts = v * D2R;
	    },
	    lon_0: function(v) {
	      self.long0 = v * D2R;
	    },
	    lon_1: function(v) {
	      self.long1 = v * D2R;
	    },
	    lon_2: function(v) {
	      self.long2 = v * D2R;
	    },
	    alpha: function(v) {
	      self.alpha = parseFloat(v) * D2R;
	    },
	    lonc: function(v) {
	      self.longc = v * D2R;
	    },
	    x_0: function(v) {
	      self.x0 = parseFloat(v);
	    },
	    y_0: function(v) {
	      self.y0 = parseFloat(v);
	    },
	    k_0: function(v) {
	      self.k0 = parseFloat(v);
	    },
	    k: function(v) {
	      self.k0 = parseFloat(v);
	    },
	    a: function(v) {
	      self.a = parseFloat(v);
	    },
	    b: function(v) {
	      self.b = parseFloat(v);
	    },
	    r_a: function() {
	      self.R_A = true;
	    },
	    zone: function(v) {
	      self.zone = parseInt(v, 10);
	    },
	    south: function() {
	      self.utmSouth = true;
	    },
	    towgs84: function(v) {
	      self.datum_params = v.split(",").map(function(a) {
	        return parseFloat(a);
	      });
	    },
	    to_meter: function(v) {
	      self.to_meter = parseFloat(v);
	    },
	    units: function(v) {
	      self.units = v;
	      var unit = match(units, v);
	      if (unit) {
	        self.to_meter = unit.to_meter;
	      }
	    },
	    from_greenwich: function(v) {
	      self.from_greenwich = v * D2R;
	    },
	    pm: function(v) {
	      var pm = match(exports$1, v);
	      self.from_greenwich = (pm ? pm : parseFloat(v)) * D2R;
	    },
	    nadgrids: function(v) {
	      if (v === '@null') {
	        self.datumCode = 'none';
	      }
	      else {
	        self.nadgrids = v;
	      }
	    },
	    axis: function(v) {
	      var legalAxis = "ewnsud";
	      if (v.length === 3 && legalAxis.indexOf(v.substr(0, 1)) !== -1 && legalAxis.indexOf(v.substr(1, 1)) !== -1 && legalAxis.indexOf(v.substr(2, 1)) !== -1) {
	        self.axis = v;
	      }
	    }
	  };
	  for (paramName in paramObj) {
	    paramVal = paramObj[paramName];
	    if (paramName in params) {
	      paramOutname = params[paramName];
	      if (typeof paramOutname === 'function') {
	        paramOutname(paramVal);
	      }
	      else {
	        self[paramOutname] = paramVal;
	      }
	    }
	    else {
	      self[paramName] = paramVal;
	    }
	  }
	  if(typeof self.datumCode === 'string' && self.datumCode !== "WGS84"){
	    self.datumCode = self.datumCode.toLowerCase();
	  }
	  return self;
	};

	var NEUTRAL = 1;
	var KEYWORD = 2;
	var NUMBER = 3;
	var QUOTED = 4;
	var AFTERQUOTE = 5;
	var ENDED = -1;
	var whitespace = /\s/;
	var latin = /[A-Za-z]/;
	var keyword = /[A-Za-z84]/;
	var endThings = /[,\]]/;
	var digets = /[\d\.E\-\+]/;
	// const ignoredChar = /[\s_\-\/\(\)]/g;
	function Parser(text) {
	  if (typeof text !== 'string') {
	    throw new Error('not a string');
	  }
	  this.text = text.trim();
	  this.level = 0;
	  this.place = 0;
	  this.root = null;
	  this.stack = [];
	  this.currentObject = null;
	  this.state = NEUTRAL;
	}
	Parser.prototype.readCharicter = function() {
	  var char = this.text[this.place++];
	  if (this.state !== QUOTED) {
	    while (whitespace.test(char)) {
	      if (this.place >= this.text.length) {
	        return;
	      }
	      char = this.text[this.place++];
	    }
	  }
	  switch (this.state) {
	    case NEUTRAL:
	      return this.neutral(char);
	    case KEYWORD:
	      return this.keyword(char)
	    case QUOTED:
	      return this.quoted(char);
	    case AFTERQUOTE:
	      return this.afterquote(char);
	    case NUMBER:
	      return this.number(char);
	    case ENDED:
	      return;
	  }
	};
	Parser.prototype.afterquote = function(char) {
	  if (char === '"') {
	    this.word += '"';
	    this.state = QUOTED;
	    return;
	  }
	  if (endThings.test(char)) {
	    this.word = this.word.trim();
	    this.afterItem(char);
	    return;
	  }
	  throw new Error('havn\'t handled "' +char + '" in afterquote yet, index ' + this.place);
	};
	Parser.prototype.afterItem = function(char) {
	  if (char === ',') {
	    if (this.word !== null) {
	      this.currentObject.push(this.word);
	    }
	    this.word = null;
	    this.state = NEUTRAL;
	    return;
	  }
	  if (char === ']') {
	    this.level--;
	    if (this.word !== null) {
	      this.currentObject.push(this.word);
	      this.word = null;
	    }
	    this.state = NEUTRAL;
	    this.currentObject = this.stack.pop();
	    if (!this.currentObject) {
	      this.state = ENDED;
	    }

	    return;
	  }
	};
	Parser.prototype.number = function(char) {
	  if (digets.test(char)) {
	    this.word += char;
	    return;
	  }
	  if (endThings.test(char)) {
	    this.word = parseFloat(this.word);
	    this.afterItem(char);
	    return;
	  }
	  throw new Error('havn\'t handled "' +char + '" in number yet, index ' + this.place);
	};
	Parser.prototype.quoted = function(char) {
	  if (char === '"') {
	    this.state = AFTERQUOTE;
	    return;
	  }
	  this.word += char;
	  return;
	};
	Parser.prototype.keyword = function(char) {
	  if (keyword.test(char)) {
	    this.word += char;
	    return;
	  }
	  if (char === '[') {
	    var newObjects = [];
	    newObjects.push(this.word);
	    this.level++;
	    if (this.root === null) {
	      this.root = newObjects;
	    } else {
	      this.currentObject.push(newObjects);
	    }
	    this.stack.push(this.currentObject);
	    this.currentObject = newObjects;
	    this.state = NEUTRAL;
	    return;
	  }
	  if (endThings.test(char)) {
	    this.afterItem(char);
	    return;
	  }
	  throw new Error('havn\'t handled "' +char + '" in keyword yet, index ' + this.place);
	};
	Parser.prototype.neutral = function(char) {
	  if (latin.test(char)) {
	    this.word = char;
	    this.state = KEYWORD;
	    return;
	  }
	  if (char === '"') {
	    this.word = '';
	    this.state = QUOTED;
	    return;
	  }
	  if (digets.test(char)) {
	    this.word = char;
	    this.state = NUMBER;
	    return;
	  }
	  if (endThings.test(char)) {
	    this.afterItem(char);
	    return;
	  }
	  throw new Error('havn\'t handled "' +char + '" in neutral yet, index ' + this.place);
	};
	Parser.prototype.output = function() {
	  while (this.place < this.text.length) {
	    this.readCharicter();
	  }
	  if (this.state === ENDED) {
	    return this.root;
	  }
	  throw new Error('unable to parse string "' +this.text + '". State is ' + this.state);
	};

	function parseString(txt) {
	  var parser = new Parser(txt);
	  return parser.output();
	}

	function mapit(obj, key, value) {
	  if (Array.isArray(key)) {
	    value.unshift(key);
	    key = null;
	  }
	  var thing = key ? {} : obj;

	  var out = value.reduce(function(newObj, item) {
	    sExpr(item, newObj);
	    return newObj
	  }, thing);
	  if (key) {
	    obj[key] = out;
	  }
	}

	function sExpr(v, obj) {
	  if (!Array.isArray(v)) {
	    obj[v] = true;
	    return;
	  }
	  var key = v.shift();
	  if (key === 'PARAMETER') {
	    key = v.shift();
	  }
	  if (v.length === 1) {
	    if (Array.isArray(v[0])) {
	      obj[key] = {};
	      sExpr(v[0], obj[key]);
	      return;
	    }
	    obj[key] = v[0];
	    return;
	  }
	  if (!v.length) {
	    obj[key] = true;
	    return;
	  }
	  if (key === 'TOWGS84') {
	    obj[key] = v;
	    return;
	  }
	  if (!Array.isArray(key)) {
	    obj[key] = {};
	  }

	  var i;
	  switch (key) {
	    case 'UNIT':
	    case 'PRIMEM':
	    case 'VERT_DATUM':
	      obj[key] = {
	        name: v[0].toLowerCase(),
	        convert: v[1]
	      };
	      if (v.length === 3) {
	        sExpr(v[2], obj[key]);
	      }
	      return;
	    case 'SPHEROID':
	    case 'ELLIPSOID':
	      obj[key] = {
	        name: v[0],
	        a: v[1],
	        rf: v[2]
	      };
	      if (v.length === 4) {
	        sExpr(v[3], obj[key]);
	      }
	      return;
	    case 'PROJECTEDCRS':
	    case 'PROJCRS':
	    case 'GEOGCS':
	    case 'GEOCCS':
	    case 'PROJCS':
	    case 'LOCAL_CS':
	    case 'GEODCRS':
	    case 'GEODETICCRS':
	    case 'GEODETICDATUM':
	    case 'EDATUM':
	    case 'ENGINEERINGDATUM':
	    case 'VERT_CS':
	    case 'VERTCRS':
	    case 'VERTICALCRS':
	    case 'COMPD_CS':
	    case 'COMPOUNDCRS':
	    case 'ENGINEERINGCRS':
	    case 'ENGCRS':
	    case 'FITTED_CS':
	    case 'LOCAL_DATUM':
	    case 'DATUM':
	      v[0] = ['name', v[0]];
	      mapit(obj, key, v);
	      return;
	    default:
	      i = -1;
	      while (++i < v.length) {
	        if (!Array.isArray(v[i])) {
	          return sExpr(v, obj[key]);
	        }
	      }
	      return mapit(obj, key, v);
	  }
	}

	var D2R$1 = 0.01745329251994329577;
	function rename(obj, params) {
	  var outName = params[0];
	  var inName = params[1];
	  if (!(outName in obj) && (inName in obj)) {
	    obj[outName] = obj[inName];
	    if (params.length === 3) {
	      obj[outName] = params[2](obj[outName]);
	    }
	  }
	}

	function d2r(input) {
	  return input * D2R$1;
	}

	function cleanWKT(wkt) {
	  if (wkt.type === 'GEOGCS') {
	    wkt.projName = 'longlat';
	  } else if (wkt.type === 'LOCAL_CS') {
	    wkt.projName = 'identity';
	    wkt.local = true;
	  } else {
	    if (typeof wkt.PROJECTION === 'object') {
	      wkt.projName = Object.keys(wkt.PROJECTION)[0];
	    } else {
	      wkt.projName = wkt.PROJECTION;
	    }
	  }
	  if (wkt.UNIT) {
	    wkt.units = wkt.UNIT.name.toLowerCase();
	    if (wkt.units === 'metre') {
	      wkt.units = 'meter';
	    }
	    if (wkt.UNIT.convert) {
	      if (wkt.type === 'GEOGCS') {
	        if (wkt.DATUM && wkt.DATUM.SPHEROID) {
	          wkt.to_meter = wkt.UNIT.convert*wkt.DATUM.SPHEROID.a;
	        }
	      } else {
	        wkt.to_meter = wkt.UNIT.convert, 10;
	      }
	    }
	  }
	  var geogcs = wkt.GEOGCS;
	  if (wkt.type === 'GEOGCS') {
	    geogcs = wkt;
	  }
	  if (geogcs) {
	    //if(wkt.GEOGCS.PRIMEM&&wkt.GEOGCS.PRIMEM.convert){
	    //  wkt.from_greenwich=wkt.GEOGCS.PRIMEM.convert*D2R;
	    //}
	    if (geogcs.DATUM) {
	      wkt.datumCode = geogcs.DATUM.name.toLowerCase();
	    } else {
	      wkt.datumCode = geogcs.name.toLowerCase();
	    }
	    if (wkt.datumCode.slice(0, 2) === 'd_') {
	      wkt.datumCode = wkt.datumCode.slice(2);
	    }
	    if (wkt.datumCode === 'new_zealand_geodetic_datum_1949' || wkt.datumCode === 'new_zealand_1949') {
	      wkt.datumCode = 'nzgd49';
	    }
	    if (wkt.datumCode === 'wgs_1984') {
	      if (wkt.PROJECTION === 'Mercator_Auxiliary_Sphere') {
	        wkt.sphere = true;
	      }
	      wkt.datumCode = 'wgs84';
	    }
	    if (wkt.datumCode.slice(-6) === '_ferro') {
	      wkt.datumCode = wkt.datumCode.slice(0, - 6);
	    }
	    if (wkt.datumCode.slice(-8) === '_jakarta') {
	      wkt.datumCode = wkt.datumCode.slice(0, - 8);
	    }
	    if (~wkt.datumCode.indexOf('belge')) {
	      wkt.datumCode = 'rnb72';
	    }
	    if (geogcs.DATUM && geogcs.DATUM.SPHEROID) {
	      wkt.ellps = geogcs.DATUM.SPHEROID.name.replace('_19', '').replace(/[Cc]larke\_18/, 'clrk');
	      if (wkt.ellps.toLowerCase().slice(0, 13) === 'international') {
	        wkt.ellps = 'intl';
	      }

	      wkt.a = geogcs.DATUM.SPHEROID.a;
	      wkt.rf = parseFloat(geogcs.DATUM.SPHEROID.rf, 10);
	    }
	    if (~wkt.datumCode.indexOf('osgb_1936')) {
	      wkt.datumCode = 'osgb36';
	    }
	    if (~wkt.datumCode.indexOf('osni_1952')) {
	      wkt.datumCode = 'osni52';
	    }
	    if (~wkt.datumCode.indexOf('tm65')
	      || ~wkt.datumCode.indexOf('geodetic_datum_of_1965')) {
	      wkt.datumCode = 'ire65';
	    }
	  }
	  if (wkt.b && !isFinite(wkt.b)) {
	    wkt.b = wkt.a;
	  }

	  function toMeter(input) {
	    var ratio = wkt.to_meter || 1;
	    return input * ratio;
	  }
	  var renamer = function(a) {
	    return rename(wkt, a);
	  };
	  var list = [
	    ['standard_parallel_1', 'Standard_Parallel_1'],
	    ['standard_parallel_2', 'Standard_Parallel_2'],
	    ['false_easting', 'False_Easting'],
	    ['false_northing', 'False_Northing'],
	    ['central_meridian', 'Central_Meridian'],
	    ['latitude_of_origin', 'Latitude_Of_Origin'],
	    ['latitude_of_origin', 'Central_Parallel'],
	    ['scale_factor', 'Scale_Factor'],
	    ['k0', 'scale_factor'],
	    ['latitude_of_center', 'Latitude_of_center'],
	    ['lat0', 'latitude_of_center', d2r],
	    ['longitude_of_center', 'Longitude_Of_Center'],
	    ['longc', 'longitude_of_center', d2r],
	    ['x0', 'false_easting', toMeter],
	    ['y0', 'false_northing', toMeter],
	    ['long0', 'central_meridian', d2r],
	    ['lat0', 'latitude_of_origin', d2r],
	    ['lat0', 'standard_parallel_1', d2r],
	    ['lat1', 'standard_parallel_1', d2r],
	    ['lat2', 'standard_parallel_2', d2r],
	    ['alpha', 'azimuth', d2r],
	    ['srsCode', 'name']
	  ];
	  list.forEach(renamer);
	  if (!wkt.long0 && wkt.longc && (wkt.projName === 'Albers_Conic_Equal_Area' || wkt.projName === 'Lambert_Azimuthal_Equal_Area')) {
	    wkt.long0 = wkt.longc;
	  }
	  if (!wkt.lat_ts && wkt.lat1 && (wkt.projName === 'Stereographic_South_Pole' || wkt.projName === 'Polar Stereographic (variant B)')) {
	    wkt.lat0 = d2r(wkt.lat1 > 0 ? 90 : -90);
	    wkt.lat_ts = wkt.lat1;
	  }
	}
	var wkt = function(wkt) {
	  var lisp = parseString(wkt);
	  var type = lisp.shift();
	  var name = lisp.shift();
	  lisp.unshift(['name', name]);
	  lisp.unshift(['type', type]);
	  var obj = {};
	  sExpr(lisp, obj);
	  cleanWKT(obj);
	  return obj;
	};

	function defs(name) {
	  /*global console*/
	  var that = this;
	  if (arguments.length === 2) {
	    var def = arguments[1];
	    if (typeof def === 'string') {
	      if (def.charAt(0) === '+') {
	        defs[name] = parseProj(arguments[1]);
	      }
	      else {
	        defs[name] = wkt(arguments[1]);
	      }
	    } else {
	      defs[name] = def;
	    }
	  }
	  else if (arguments.length === 1) {
	    if (Array.isArray(name)) {
	      return name.map(function(v) {
	        if (Array.isArray(v)) {
	          defs.apply(that, v);
	        }
	        else {
	          defs(v);
	        }
	      });
	    }
	    else if (typeof name === 'string') {
	      if (name in defs) {
	        return defs[name];
	      }
	    }
	    else if ('EPSG' in name) {
	      defs['EPSG:' + name.EPSG] = name;
	    }
	    else if ('ESRI' in name) {
	      defs['ESRI:' + name.ESRI] = name;
	    }
	    else if ('IAU2000' in name) {
	      defs['IAU2000:' + name.IAU2000] = name;
	    }
	    else {
	      console.log(name);
	    }
	    return;
	  }


	}
	globals(defs);

	function testObj(code){
	  return typeof code === 'string';
	}
	function testDef(code){
	  return code in defs;
	}
	 var codeWords = ['PROJECTEDCRS', 'PROJCRS', 'GEOGCS','GEOCCS','PROJCS','LOCAL_CS', 'GEODCRS', 'GEODETICCRS', 'GEODETICDATUM', 'ENGCRS', 'ENGINEERINGCRS']; 
	function testWKT(code){
	  return codeWords.some(function (word) {
	    return code.indexOf(word) > -1;
	  });
	}
	function testProj(code){
	  return code[0] === '+';
	}
	function parse(code){
	  if (testObj(code)) {
	    //check to see if this is a WKT string
	    if (testDef(code)) {
	      return defs[code];
	    }
	    if (testWKT(code)) {
	      return wkt(code);
	    }
	    if (testProj(code)) {
	      return parseProj(code);
	    }
	  }else{
	    return code;
	  }
	}

	var extend = function(destination, source) {
	  destination = destination || {};
	  var value, property;
	  if (!source) {
	    return destination;
	  }
	  for (property in source) {
	    value = source[property];
	    if (value !== undefined) {
	      destination[property] = value;
	    }
	  }
	  return destination;
	};

	var msfnz = function(eccent, sinphi, cosphi) {
	  var con = eccent * sinphi;
	  return cosphi / (Math.sqrt(1 - con * con));
	};

	var sign = function(x) {
	  return x<0 ? -1 : 1;
	};

	var adjust_lon = function(x) {
	  return (Math.abs(x) <= SPI) ? x : (x - (sign(x) * TWO_PI));
	};

	var tsfnz = function(eccent, phi, sinphi) {
	  var con = eccent * sinphi;
	  var com = 0.5 * eccent;
	  con = Math.pow(((1 - con) / (1 + con)), com);
	  return (Math.tan(0.5 * (HALF_PI - phi)) / con);
	};

	var phi2z = function(eccent, ts) {
	  var eccnth = 0.5 * eccent;
	  var con, dphi;
	  var phi = HALF_PI - 2 * Math.atan(ts);
	  for (var i = 0; i <= 15; i++) {
	    con = eccent * Math.sin(phi);
	    dphi = HALF_PI - 2 * Math.atan(ts * (Math.pow(((1 - con) / (1 + con)), eccnth))) - phi;
	    phi += dphi;
	    if (Math.abs(dphi) <= 0.0000000001) {
	      return phi;
	    }
	  }
	  //console.log("phi2z has NoConvergence");
	  return -9999;
	};

	function init() {
	  var con = this.b / this.a;
	  this.es = 1 - con * con;
	  if(!('x0' in this)){
	    this.x0 = 0;
	  }
	  if(!('y0' in this)){
	    this.y0 = 0;
	  }
	  this.e = Math.sqrt(this.es);
	  if (this.lat_ts) {
	    if (this.sphere) {
	      this.k0 = Math.cos(this.lat_ts);
	    }
	    else {
	      this.k0 = msfnz(this.e, Math.sin(this.lat_ts), Math.cos(this.lat_ts));
	    }
	  }
	  else {
	    if (!this.k0) {
	      if (this.k) {
	        this.k0 = this.k;
	      }
	      else {
	        this.k0 = 1;
	      }
	    }
	  }
	}

	/* Mercator forward equations--mapping lat,long to x,y
	  --------------------------------------------------*/

	function forward(p) {
	  var lon = p.x;
	  var lat = p.y;
	  // convert to radians
	  if (lat * R2D > 90 && lat * R2D < -90 && lon * R2D > 180 && lon * R2D < -180) {
	    return null;
	  }

	  var x, y;
	  if (Math.abs(Math.abs(lat) - HALF_PI) <= EPSLN) {
	    return null;
	  }
	  else {
	    if (this.sphere) {
	      x = this.x0 + this.a * this.k0 * adjust_lon(lon - this.long0);
	      y = this.y0 + this.a * this.k0 * Math.log(Math.tan(FORTPI + 0.5 * lat));
	    }
	    else {
	      var sinphi = Math.sin(lat);
	      var ts = tsfnz(this.e, lat, sinphi);
	      x = this.x0 + this.a * this.k0 * adjust_lon(lon - this.long0);
	      y = this.y0 - this.a * this.k0 * Math.log(ts);
	    }
	    p.x = x;
	    p.y = y;
	    return p;
	  }
	}

	/* Mercator inverse equations--mapping x,y to lat/long
	  --------------------------------------------------*/
	function inverse(p) {

	  var x = p.x - this.x0;
	  var y = p.y - this.y0;
	  var lon, lat;

	  if (this.sphere) {
	    lat = HALF_PI - 2 * Math.atan(Math.exp(-y / (this.a * this.k0)));
	  }
	  else {
	    var ts = Math.exp(-y / (this.a * this.k0));
	    lat = phi2z(this.e, ts);
	    if (lat === -9999) {
	      return null;
	    }
	  }
	  lon = adjust_lon(this.long0 + x / (this.a * this.k0));

	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$1 = ["Mercator", "Popular Visualisation Pseudo Mercator", "Mercator_1SP", "Mercator_Auxiliary_Sphere", "merc"];
	var merc = {
	  init: init,
	  forward: forward,
	  inverse: inverse,
	  names: names$1
	};

	function init$1() {
	  //no-op for longlat
	}

	function identity(pt) {
	  return pt;
	}
	var names$2 = ["longlat", "identity"];
	var longlat = {
	  init: init$1,
	  forward: identity,
	  inverse: identity,
	  names: names$2
	};

	var projs = [merc, longlat];
	var names$$1 = {};
	var projStore = [];

	function add(proj, i) {
	  var len = projStore.length;
	  if (!proj.names) {
	    console.log(i);
	    return true;
	  }
	  projStore[len] = proj;
	  proj.names.forEach(function(n) {
	    names$$1[n.toLowerCase()] = len;
	  });
	  return this;
	}

	function get(name) {
	  if (!name) {
	    return false;
	  }
	  var n = name.toLowerCase();
	  if (typeof names$$1[n] !== 'undefined' && projStore[names$$1[n]]) {
	    return projStore[names$$1[n]];
	  }
	}

	function start() {
	  projs.forEach(add);
	}
	var projections = {
	  start: start,
	  add: add,
	  get: get
	};

	var exports$2 = {};
	exports$2.MERIT = {
	  a: 6378137.0,
	  rf: 298.257,
	  ellipseName: "MERIT 1983"
	};

	exports$2.SGS85 = {
	  a: 6378136.0,
	  rf: 298.257,
	  ellipseName: "Soviet Geodetic System 85"
	};

	exports$2.GRS80 = {
	  a: 6378137.0,
	  rf: 298.257222101,
	  ellipseName: "GRS 1980(IUGG, 1980)"
	};

	exports$2.IAU76 = {
	  a: 6378140.0,
	  rf: 298.257,
	  ellipseName: "IAU 1976"
	};

	exports$2.airy = {
	  a: 6377563.396,
	  b: 6356256.910,
	  ellipseName: "Airy 1830"
	};

	exports$2.APL4 = {
	  a: 6378137,
	  rf: 298.25,
	  ellipseName: "Appl. Physics. 1965"
	};

	exports$2.NWL9D = {
	  a: 6378145.0,
	  rf: 298.25,
	  ellipseName: "Naval Weapons Lab., 1965"
	};

	exports$2.mod_airy = {
	  a: 6377340.189,
	  b: 6356034.446,
	  ellipseName: "Modified Airy"
	};

	exports$2.andrae = {
	  a: 6377104.43,
	  rf: 300.0,
	  ellipseName: "Andrae 1876 (Den., Iclnd.)"
	};

	exports$2.aust_SA = {
	  a: 6378160.0,
	  rf: 298.25,
	  ellipseName: "Australian Natl & S. Amer. 1969"
	};

	exports$2.GRS67 = {
	  a: 6378160.0,
	  rf: 298.2471674270,
	  ellipseName: "GRS 67(IUGG 1967)"
	};

	exports$2.bessel = {
	  a: 6377397.155,
	  rf: 299.1528128,
	  ellipseName: "Bessel 1841"
	};

	exports$2.bess_nam = {
	  a: 6377483.865,
	  rf: 299.1528128,
	  ellipseName: "Bessel 1841 (Namibia)"
	};

	exports$2.clrk66 = {
	  a: 6378206.4,
	  b: 6356583.8,
	  ellipseName: "Clarke 1866"
	};

	exports$2.clrk80 = {
	  a: 6378249.145,
	  rf: 293.4663,
	  ellipseName: "Clarke 1880 mod."
	};

	exports$2.clrk58 = {
	  a: 6378293.645208759,
	  rf: 294.2606763692654,
	  ellipseName: "Clarke 1858"
	};

	exports$2.CPM = {
	  a: 6375738.7,
	  rf: 334.29,
	  ellipseName: "Comm. des Poids et Mesures 1799"
	};

	exports$2.delmbr = {
	  a: 6376428.0,
	  rf: 311.5,
	  ellipseName: "Delambre 1810 (Belgium)"
	};

	exports$2.engelis = {
	  a: 6378136.05,
	  rf: 298.2566,
	  ellipseName: "Engelis 1985"
	};

	exports$2.evrst30 = {
	  a: 6377276.345,
	  rf: 300.8017,
	  ellipseName: "Everest 1830"
	};

	exports$2.evrst48 = {
	  a: 6377304.063,
	  rf: 300.8017,
	  ellipseName: "Everest 1948"
	};

	exports$2.evrst56 = {
	  a: 6377301.243,
	  rf: 300.8017,
	  ellipseName: "Everest 1956"
	};

	exports$2.evrst69 = {
	  a: 6377295.664,
	  rf: 300.8017,
	  ellipseName: "Everest 1969"
	};

	exports$2.evrstSS = {
	  a: 6377298.556,
	  rf: 300.8017,
	  ellipseName: "Everest (Sabah & Sarawak)"
	};

	exports$2.fschr60 = {
	  a: 6378166.0,
	  rf: 298.3,
	  ellipseName: "Fischer (Mercury Datum) 1960"
	};

	exports$2.fschr60m = {
	  a: 6378155.0,
	  rf: 298.3,
	  ellipseName: "Fischer 1960"
	};

	exports$2.fschr68 = {
	  a: 6378150.0,
	  rf: 298.3,
	  ellipseName: "Fischer 1968"
	};

	exports$2.helmert = {
	  a: 6378200.0,
	  rf: 298.3,
	  ellipseName: "Helmert 1906"
	};

	exports$2.hough = {
	  a: 6378270.0,
	  rf: 297.0,
	  ellipseName: "Hough"
	};

	exports$2.intl = {
	  a: 6378388.0,
	  rf: 297.0,
	  ellipseName: "International 1909 (Hayford)"
	};

	exports$2.kaula = {
	  a: 6378163.0,
	  rf: 298.24,
	  ellipseName: "Kaula 1961"
	};

	exports$2.lerch = {
	  a: 6378139.0,
	  rf: 298.257,
	  ellipseName: "Lerch 1979"
	};

	exports$2.mprts = {
	  a: 6397300.0,
	  rf: 191.0,
	  ellipseName: "Maupertius 1738"
	};

	exports$2.new_intl = {
	  a: 6378157.5,
	  b: 6356772.2,
	  ellipseName: "New International 1967"
	};

	exports$2.plessis = {
	  a: 6376523.0,
	  rf: 6355863.0,
	  ellipseName: "Plessis 1817 (France)"
	};

	exports$2.krass = {
	  a: 6378245.0,
	  rf: 298.3,
	  ellipseName: "Krassovsky, 1942"
	};

	exports$2.SEasia = {
	  a: 6378155.0,
	  b: 6356773.3205,
	  ellipseName: "Southeast Asia"
	};

	exports$2.walbeck = {
	  a: 6376896.0,
	  b: 6355834.8467,
	  ellipseName: "Walbeck"
	};

	exports$2.WGS60 = {
	  a: 6378165.0,
	  rf: 298.3,
	  ellipseName: "WGS 60"
	};

	exports$2.WGS66 = {
	  a: 6378145.0,
	  rf: 298.25,
	  ellipseName: "WGS 66"
	};

	exports$2.WGS7 = {
	  a: 6378135.0,
	  rf: 298.26,
	  ellipseName: "WGS 72"
	};

	var WGS84 = exports$2.WGS84 = {
	  a: 6378137.0,
	  rf: 298.257223563,
	  ellipseName: "WGS 84"
	};

	exports$2.sphere = {
	  a: 6370997.0,
	  b: 6370997.0,
	  ellipseName: "Normal Sphere (r=6370997)"
	};

	function eccentricity(a, b, rf, R_A) {
	  var a2 = a * a; // used in geocentric
	  var b2 = b * b; // used in geocentric
	  var es = (a2 - b2) / a2; // e ^ 2
	  var e = 0;
	  if (R_A) {
	    a *= 1 - es * (SIXTH + es * (RA4 + es * RA6));
	    a2 = a * a;
	    es = 0;
	  } else {
	    e = Math.sqrt(es); // eccentricity
	  }
	  var ep2 = (a2 - b2) / b2; // used in geocentric
	  return {
	    es: es,
	    e: e,
	    ep2: ep2
	  };
	}
	function sphere(a, b, rf, ellps, sphere) {
	  if (!a) { // do we have an ellipsoid?
	    var ellipse = match(exports$2, ellps);
	    if (!ellipse) {
	      ellipse = WGS84;
	    }
	    a = ellipse.a;
	    b = ellipse.b;
	    rf = ellipse.rf;
	  }

	  if (rf && !b) {
	    b = (1.0 - 1.0 / rf) * a;
	  }
	  if (rf === 0 || Math.abs(a - b) < EPSLN) {
	    sphere = true;
	    b = a;
	  }
	  return {
	    a: a,
	    b: b,
	    rf: rf,
	    sphere: sphere
	  };
	}

	var exports$3 = {};
	exports$3.wgs84 = {
	  towgs84: "0,0,0",
	  ellipse: "WGS84",
	  datumName: "WGS84"
	};

	exports$3.ch1903 = {
	  towgs84: "674.374,15.056,405.346",
	  ellipse: "bessel",
	  datumName: "swiss"
	};

	exports$3.ggrs87 = {
	  towgs84: "-199.87,74.79,246.62",
	  ellipse: "GRS80",
	  datumName: "Greek_Geodetic_Reference_System_1987"
	};

	exports$3.nad83 = {
	  towgs84: "0,0,0",
	  ellipse: "GRS80",
	  datumName: "North_American_Datum_1983"
	};

	exports$3.nad27 = {
	  nadgrids: "@conus,@alaska,@ntv2_0.gsb,@ntv1_can.dat",
	  ellipse: "clrk66",
	  datumName: "North_American_Datum_1927"
	};

	exports$3.potsdam = {
	  towgs84: "606.0,23.0,413.0",
	  ellipse: "bessel",
	  datumName: "Potsdam Rauenberg 1950 DHDN"
	};

	exports$3.carthage = {
	  towgs84: "-263.0,6.0,431.0",
	  ellipse: "clark80",
	  datumName: "Carthage 1934 Tunisia"
	};

	exports$3.hermannskogel = {
	  towgs84: "653.0,-212.0,449.0",
	  ellipse: "bessel",
	  datumName: "Hermannskogel"
	};

	exports$3.osni52 = {
	  towgs84: "482.530,-130.596,564.557,-1.042,-0.214,-0.631,8.15",
	  ellipse: "airy",
	  datumName: "Irish National"
	};

	exports$3.ire65 = {
	  towgs84: "482.530,-130.596,564.557,-1.042,-0.214,-0.631,8.15",
	  ellipse: "mod_airy",
	  datumName: "Ireland 1965"
	};

	exports$3.rassadiran = {
	  towgs84: "-133.63,-157.5,-158.62",
	  ellipse: "intl",
	  datumName: "Rassadiran"
	};

	exports$3.nzgd49 = {
	  towgs84: "59.47,-5.04,187.44,0.47,-0.1,1.024,-4.5993",
	  ellipse: "intl",
	  datumName: "New Zealand Geodetic Datum 1949"
	};

	exports$3.osgb36 = {
	  towgs84: "446.448,-125.157,542.060,0.1502,0.2470,0.8421,-20.4894",
	  ellipse: "airy",
	  datumName: "Airy 1830"
	};

	exports$3.s_jtsk = {
	  towgs84: "589,76,480",
	  ellipse: 'bessel',
	  datumName: 'S-JTSK (Ferro)'
	};

	exports$3.beduaram = {
	  towgs84: '-106,-87,188',
	  ellipse: 'clrk80',
	  datumName: 'Beduaram'
	};

	exports$3.gunung_segara = {
	  towgs84: '-403,684,41',
	  ellipse: 'bessel',
	  datumName: 'Gunung Segara Jakarta'
	};

	exports$3.rnb72 = {
	  towgs84: "106.869,-52.2978,103.724,-0.33657,0.456955,-1.84218,1",
	  ellipse: "intl",
	  datumName: "Reseau National Belge 1972"
	};

	function datum(datumCode, datum_params, a, b, es, ep2) {
	  var out = {};

	  if (datumCode === undefined || datumCode === 'none') {
	    out.datum_type = PJD_NODATUM;
	  } else {
	    out.datum_type = PJD_WGS84;
	  }

	  if (datum_params) {
	    out.datum_params = datum_params.map(parseFloat);
	    if (out.datum_params[0] !== 0 || out.datum_params[1] !== 0 || out.datum_params[2] !== 0) {
	      out.datum_type = PJD_3PARAM;
	    }
	    if (out.datum_params.length > 3) {
	      if (out.datum_params[3] !== 0 || out.datum_params[4] !== 0 || out.datum_params[5] !== 0 || out.datum_params[6] !== 0) {
	        out.datum_type = PJD_7PARAM;
	        out.datum_params[3] *= SEC_TO_RAD;
	        out.datum_params[4] *= SEC_TO_RAD;
	        out.datum_params[5] *= SEC_TO_RAD;
	        out.datum_params[6] = (out.datum_params[6] / 1000000.0) + 1.0;
	      }
	    }
	  }

	  out.a = a; //datum object also uses these values
	  out.b = b;
	  out.es = es;
	  out.ep2 = ep2;
	  return out;
	}

	function Projection$1(srsCode,callback) {
	  if (!(this instanceof Projection$1)) {
	    return new Projection$1(srsCode);
	  }
	  callback = callback || function(error){
	    if(error){
	      throw error;
	    }
	  };
	  var json = parse(srsCode);
	  if(typeof json !== 'object'){
	    callback(srsCode);
	    return;
	  }
	  var ourProj = Projection$1.projections.get(json.projName);
	  if(!ourProj){
	    callback(srsCode);
	    return;
	  }
	  if (json.datumCode && json.datumCode !== 'none') {
	    var datumDef = match(exports$3, json.datumCode);
	    if (datumDef) {
	      json.datum_params = datumDef.towgs84 ? datumDef.towgs84.split(',') : null;
	      json.ellps = datumDef.ellipse;
	      json.datumName = datumDef.datumName ? datumDef.datumName : json.datumCode;
	    }
	  }
	  json.k0 = json.k0 || 1.0;
	  json.axis = json.axis || 'enu';
	  json.ellps = json.ellps || 'wgs84';
	  var sphere_ = sphere(json.a, json.b, json.rf, json.ellps, json.sphere);
	  var ecc = eccentricity(sphere_.a, sphere_.b, sphere_.rf, json.R_A);
	  var datumObj = json.datum || datum(json.datumCode, json.datum_params, sphere_.a, sphere_.b, ecc.es, ecc.ep2);

	  extend(this, json); // transfer everything over from the projection because we don't know what we'll need
	  extend(this, ourProj); // transfer all the methods from the projection

	  // copy the 4 things over we calulated in deriveConstants.sphere
	  this.a = sphere_.a;
	  this.b = sphere_.b;
	  this.rf = sphere_.rf;
	  this.sphere = sphere_.sphere;

	  // copy the 3 things we calculated in deriveConstants.eccentricity
	  this.es = ecc.es;
	  this.e = ecc.e;
	  this.ep2 = ecc.ep2;

	  // add in the datum object
	  this.datum = datumObj;

	  // init the projection
	  this.init();

	  // legecy callback from back in the day when it went to spatialreference.org
	  callback(null, this);

	}
	Projection$1.projections = projections;
	Projection$1.projections.start();

	function compareDatums(source, dest) {
	  if (source.datum_type !== dest.datum_type) {
	    return false; // false, datums are not equal
	  } else if (source.a !== dest.a || Math.abs(source.es - dest.es) > 0.000000000050) {
	    // the tolerance for es is to ensure that GRS80 and WGS84
	    // are considered identical
	    return false;
	  } else if (source.datum_type === PJD_3PARAM) {
	    return (source.datum_params[0] === dest.datum_params[0] && source.datum_params[1] === dest.datum_params[1] && source.datum_params[2] === dest.datum_params[2]);
	  } else if (source.datum_type === PJD_7PARAM) {
	    return (source.datum_params[0] === dest.datum_params[0] && source.datum_params[1] === dest.datum_params[1] && source.datum_params[2] === dest.datum_params[2] && source.datum_params[3] === dest.datum_params[3] && source.datum_params[4] === dest.datum_params[4] && source.datum_params[5] === dest.datum_params[5] && source.datum_params[6] === dest.datum_params[6]);
	  } else {
	    return true; // datums are equal
	  }
	} // cs_compare_datums()

	/*
	 * The function Convert_Geodetic_To_Geocentric converts geodetic coordinates
	 * (latitude, longitude, and height) to geocentric coordinates (X, Y, Z),
	 * according to the current ellipsoid parameters.
	 *
	 *    Latitude  : Geodetic latitude in radians                     (input)
	 *    Longitude : Geodetic longitude in radians                    (input)
	 *    Height    : Geodetic height, in meters                       (input)
	 *    X         : Calculated Geocentric X coordinate, in meters    (output)
	 *    Y         : Calculated Geocentric Y coordinate, in meters    (output)
	 *    Z         : Calculated Geocentric Z coordinate, in meters    (output)
	 *
	 */
	function geodeticToGeocentric(p, es, a) {
	  var Longitude = p.x;
	  var Latitude = p.y;
	  var Height = p.z ? p.z : 0; //Z value not always supplied

	  var Rn; /*  Earth radius at location  */
	  var Sin_Lat; /*  Math.sin(Latitude)  */
	  var Sin2_Lat; /*  Square of Math.sin(Latitude)  */
	  var Cos_Lat; /*  Math.cos(Latitude)  */

	  /*
	   ** Don't blow up if Latitude is just a little out of the value
	   ** range as it may just be a rounding issue.  Also removed longitude
	   ** test, it should be wrapped by Math.cos() and Math.sin().  NFW for PROJ.4, Sep/2001.
	   */
	  if (Latitude < -HALF_PI && Latitude > -1.001 * HALF_PI) {
	    Latitude = -HALF_PI;
	  } else if (Latitude > HALF_PI && Latitude < 1.001 * HALF_PI) {
	    Latitude = HALF_PI;
	  } else if ((Latitude < -HALF_PI) || (Latitude > HALF_PI)) {
	    /* Latitude out of range */
	    //..reportError('geocent:lat out of range:' + Latitude);
	    return null;
	  }

	  if (Longitude > Math.PI) {
	    Longitude -= (2 * Math.PI);
	  }
	  Sin_Lat = Math.sin(Latitude);
	  Cos_Lat = Math.cos(Latitude);
	  Sin2_Lat = Sin_Lat * Sin_Lat;
	  Rn = a / (Math.sqrt(1.0e0 - es * Sin2_Lat));
	  return {
	    x: (Rn + Height) * Cos_Lat * Math.cos(Longitude),
	    y: (Rn + Height) * Cos_Lat * Math.sin(Longitude),
	    z: ((Rn * (1 - es)) + Height) * Sin_Lat
	  };
	} // cs_geodetic_to_geocentric()

	function geocentricToGeodetic(p, es, a, b) {
	  /* local defintions and variables */
	  /* end-criterium of loop, accuracy of sin(Latitude) */
	  var genau = 1e-12;
	  var genau2 = (genau * genau);
	  var maxiter = 30;

	  var P; /* distance between semi-minor axis and location */
	  var RR; /* distance between center and location */
	  var CT; /* sin of geocentric latitude */
	  var ST; /* cos of geocentric latitude */
	  var RX;
	  var RK;
	  var RN; /* Earth radius at location */
	  var CPHI0; /* cos of start or old geodetic latitude in iterations */
	  var SPHI0; /* sin of start or old geodetic latitude in iterations */
	  var CPHI; /* cos of searched geodetic latitude */
	  var SPHI; /* sin of searched geodetic latitude */
	  var SDPHI; /* end-criterium: addition-theorem of sin(Latitude(iter)-Latitude(iter-1)) */
	  var iter; /* # of continous iteration, max. 30 is always enough (s.a.) */

	  var X = p.x;
	  var Y = p.y;
	  var Z = p.z ? p.z : 0.0; //Z value not always supplied
	  var Longitude;
	  var Latitude;
	  var Height;

	  P = Math.sqrt(X * X + Y * Y);
	  RR = Math.sqrt(X * X + Y * Y + Z * Z);

	  /*      special cases for latitude and longitude */
	  if (P / a < genau) {

	    /*  special case, if P=0. (X=0., Y=0.) */
	    Longitude = 0.0;

	    /*  if (X,Y,Z)=(0.,0.,0.) then Height becomes semi-minor axis
	     *  of ellipsoid (=center of mass), Latitude becomes PI/2 */
	    if (RR / a < genau) {
	      Latitude = HALF_PI;
	      Height = -b;
	      return {
	        x: p.x,
	        y: p.y,
	        z: p.z
	      };
	    }
	  } else {
	    /*  ellipsoidal (geodetic) longitude
	     *  interval: -PI < Longitude <= +PI */
	    Longitude = Math.atan2(Y, X);
	  }

	  /* --------------------------------------------------------------
	   * Following iterative algorithm was developped by
	   * "Institut for Erdmessung", University of Hannover, July 1988.
	   * Internet: www.ife.uni-hannover.de
	   * Iterative computation of CPHI,SPHI and Height.
	   * Iteration of CPHI and SPHI to 10**-12 radian resp.
	   * 2*10**-7 arcsec.
	   * --------------------------------------------------------------
	   */
	  CT = Z / RR;
	  ST = P / RR;
	  RX = 1.0 / Math.sqrt(1.0 - es * (2.0 - es) * ST * ST);
	  CPHI0 = ST * (1.0 - es) * RX;
	  SPHI0 = CT * RX;
	  iter = 0;

	  /* loop to find sin(Latitude) resp. Latitude
	   * until |sin(Latitude(iter)-Latitude(iter-1))| < genau */
	  do {
	    iter++;
	    RN = a / Math.sqrt(1.0 - es * SPHI0 * SPHI0);

	    /*  ellipsoidal (geodetic) height */
	    Height = P * CPHI0 + Z * SPHI0 - RN * (1.0 - es * SPHI0 * SPHI0);

	    RK = es * RN / (RN + Height);
	    RX = 1.0 / Math.sqrt(1.0 - RK * (2.0 - RK) * ST * ST);
	    CPHI = ST * (1.0 - RK) * RX;
	    SPHI = CT * RX;
	    SDPHI = SPHI * CPHI0 - CPHI * SPHI0;
	    CPHI0 = CPHI;
	    SPHI0 = SPHI;
	  }
	  while (SDPHI * SDPHI > genau2 && iter < maxiter);

	  /*      ellipsoidal (geodetic) latitude */
	  Latitude = Math.atan(SPHI / Math.abs(CPHI));
	  return {
	    x: Longitude,
	    y: Latitude,
	    z: Height
	  };
	} // cs_geocentric_to_geodetic()

	/****************************************************************/
	// pj_geocentic_to_wgs84( p )
	//  p = point to transform in geocentric coordinates (x,y,z)


	/** point object, nothing fancy, just allows values to be
	    passed back and forth by reference rather than by value.
	    Other point classes may be used as long as they have
	    x and y properties, which will get modified in the transform method.
	*/
	function geocentricToWgs84(p, datum_type, datum_params) {

	  if (datum_type === PJD_3PARAM) {
	    // if( x[io] === HUGE_VAL )
	    //    continue;
	    return {
	      x: p.x + datum_params[0],
	      y: p.y + datum_params[1],
	      z: p.z + datum_params[2],
	    };
	  } else if (datum_type === PJD_7PARAM) {
	    var Dx_BF = datum_params[0];
	    var Dy_BF = datum_params[1];
	    var Dz_BF = datum_params[2];
	    var Rx_BF = datum_params[3];
	    var Ry_BF = datum_params[4];
	    var Rz_BF = datum_params[5];
	    var M_BF = datum_params[6];
	    // if( x[io] === HUGE_VAL )
	    //    continue;
	    return {
	      x: M_BF * (p.x - Rz_BF * p.y + Ry_BF * p.z) + Dx_BF,
	      y: M_BF * (Rz_BF * p.x + p.y - Rx_BF * p.z) + Dy_BF,
	      z: M_BF * (-Ry_BF * p.x + Rx_BF * p.y + p.z) + Dz_BF
	    };
	  }
	} // cs_geocentric_to_wgs84

	/****************************************************************/
	// pj_geocentic_from_wgs84()
	//  coordinate system definition,
	//  point to transform in geocentric coordinates (x,y,z)
	function geocentricFromWgs84(p, datum_type, datum_params) {

	  if (datum_type === PJD_3PARAM) {
	    //if( x[io] === HUGE_VAL )
	    //    continue;
	    return {
	      x: p.x - datum_params[0],
	      y: p.y - datum_params[1],
	      z: p.z - datum_params[2],
	    };

	  } else if (datum_type === PJD_7PARAM) {
	    var Dx_BF = datum_params[0];
	    var Dy_BF = datum_params[1];
	    var Dz_BF = datum_params[2];
	    var Rx_BF = datum_params[3];
	    var Ry_BF = datum_params[4];
	    var Rz_BF = datum_params[5];
	    var M_BF = datum_params[6];
	    var x_tmp = (p.x - Dx_BF) / M_BF;
	    var y_tmp = (p.y - Dy_BF) / M_BF;
	    var z_tmp = (p.z - Dz_BF) / M_BF;
	    //if( x[io] === HUGE_VAL )
	    //    continue;

	    return {
	      x: x_tmp + Rz_BF * y_tmp - Ry_BF * z_tmp,
	      y: -Rz_BF * x_tmp + y_tmp + Rx_BF * z_tmp,
	      z: Ry_BF * x_tmp - Rx_BF * y_tmp + z_tmp
	    };
	  } //cs_geocentric_from_wgs84()
	}

	function checkParams(type) {
	  return (type === PJD_3PARAM || type === PJD_7PARAM);
	}

	var datum_transform = function(source, dest, point) {
	  // Short cut if the datums are identical.
	  if (compareDatums(source, dest)) {
	    return point; // in this case, zero is sucess,
	    // whereas cs_compare_datums returns 1 to indicate TRUE
	    // confusing, should fix this
	  }

	  // Explicitly skip datum transform by setting 'datum=none' as parameter for either source or dest
	  if (source.datum_type === PJD_NODATUM || dest.datum_type === PJD_NODATUM) {
	    return point;
	  }

	  // If this datum requires grid shifts, then apply it to geodetic coordinates.

	  // Do we need to go through geocentric coordinates?
	  if (source.es === dest.es && source.a === dest.a && !checkParams(source.datum_type) &&  !checkParams(dest.datum_type)) {
	    return point;
	  }

	  // Convert to geocentric coordinates.
	  point = geodeticToGeocentric(point, source.es, source.a);
	  // Convert between datums
	  if (checkParams(source.datum_type)) {
	    point = geocentricToWgs84(point, source.datum_type, source.datum_params);
	  }
	  if (checkParams(dest.datum_type)) {
	    point = geocentricFromWgs84(point, dest.datum_type, dest.datum_params);
	  }
	  return geocentricToGeodetic(point, dest.es, dest.a, dest.b);

	};

	var adjust_axis = function(crs, denorm, point) {
	  var xin = point.x,
	    yin = point.y,
	    zin = point.z || 0.0;
	  var v, t, i;
	  var out = {};
	  for (i = 0; i < 3; i++) {
	    if (denorm && i === 2 && point.z === undefined) {
	      continue;
	    }
	    if (i === 0) {
	      v = xin;
	      t = 'x';
	    }
	    else if (i === 1) {
	      v = yin;
	      t = 'y';
	    }
	    else {
	      v = zin;
	      t = 'z';
	    }
	    switch (crs.axis[i]) {
	    case 'e':
	      out[t] = v;
	      break;
	    case 'w':
	      out[t] = -v;
	      break;
	    case 'n':
	      out[t] = v;
	      break;
	    case 's':
	      out[t] = -v;
	      break;
	    case 'u':
	      if (point[t] !== undefined) {
	        out.z = v;
	      }
	      break;
	    case 'd':
	      if (point[t] !== undefined) {
	        out.z = -v;
	      }
	      break;
	    default:
	      //console.log("ERROR: unknow axis ("+crs.axis[i]+") - check definition of "+crs.projName);
	      return null;
	    }
	  }
	  return out;
	};

	var toPoint = function (array){
	  var out = {
	    x: array[0],
	    y: array[1]
	  };
	  if (array.length>2) {
	    out.z = array[2];
	  }
	  if (array.length>3) {
	    out.m = array[3];
	  }
	  return out;
	};

	var checkSanity = function (point) {
	  checkCoord(point.x);
	  checkCoord(point.y);
	};
	function checkCoord(num) {
	  if (typeof Number.isFinite === 'function') {
	    if (Number.isFinite(num)) {
	      return;
	    }
	    throw new TypeError('coordinates must be finite numbers');
	  }
	  if (typeof num !== 'number' || num !== num || !isFinite(num)) {
	    throw new TypeError('coordinates must be finite numbers');
	  }
	}

	function checkNotWGS(source, dest) {
	  return ((source.datum.datum_type === PJD_3PARAM || source.datum.datum_type === PJD_7PARAM) && dest.datumCode !== 'WGS84') || ((dest.datum.datum_type === PJD_3PARAM || dest.datum.datum_type === PJD_7PARAM) && source.datumCode !== 'WGS84');
	}

	function transform(source, dest, point) {
	  var wgs84;
	  if (Array.isArray(point)) {
	    point = toPoint(point);
	  }
	  checkSanity(point);
	  // Workaround for datum shifts towgs84, if either source or destination projection is not wgs84
	  if (source.datum && dest.datum && checkNotWGS(source, dest)) {
	    wgs84 = new Projection$1('WGS84');
	    point = transform(source, wgs84, point);
	    source = wgs84;
	  }
	  // DGR, 2010/11/12
	  if (source.axis !== 'enu') {
	    point = adjust_axis(source, false, point);
	  }
	  // Transform source points to long/lat, if they aren't already.
	  if (source.projName === 'longlat') {
	    point = {
	      x: point.x * D2R,
	      y: point.y * D2R
	    };
	  }
	  else {
	    if (source.to_meter) {
	      point = {
	        x: point.x * source.to_meter,
	        y: point.y * source.to_meter
	      };
	    }
	    point = source.inverse(point); // Convert Cartesian to longlat
	  }
	  // Adjust for the prime meridian if necessary
	  if (source.from_greenwich) {
	    point.x += source.from_greenwich;
	  }

	  // Convert datums if needed, and if possible.
	  point = datum_transform(source.datum, dest.datum, point);

	  // Adjust for the prime meridian if necessary
	  if (dest.from_greenwich) {
	    point = {
	      x: point.x - dest.from_greenwich,
	      y: point.y
	    };
	  }

	  if (dest.projName === 'longlat') {
	    // convert radians to decimal degrees
	    point = {
	      x: point.x * R2D,
	      y: point.y * R2D
	    };
	  } else { // else project
	    point = dest.forward(point);
	    if (dest.to_meter) {
	      point = {
	        x: point.x / dest.to_meter,
	        y: point.y / dest.to_meter
	      };
	    }
	  }

	  // DGR, 2010/11/12
	  if (dest.axis !== 'enu') {
	    return adjust_axis(dest, true, point);
	  }

	  return point;
	}

	var wgs84 = Projection$1('WGS84');

	function transformer(from, to, coords) {
	  var transformedArray, out, keys;
	  if (Array.isArray(coords)) {
	    transformedArray = transform(from, to, coords);
	    if (coords.length === 3) {
	      return [transformedArray.x, transformedArray.y, transformedArray.z];
	    }
	    else {
	      return [transformedArray.x, transformedArray.y];
	    }
	  }
	  else {
	    out = transform(from, to, coords);
	    keys = Object.keys(coords);
	    if (keys.length === 2) {
	      return out;
	    }
	    keys.forEach(function (key) {
	      if (key === 'x' || key === 'y') {
	        return;
	      }
	      out[key] = coords[key];
	    });
	    return out;
	  }
	}

	function checkProj(item) {
	  if (item instanceof Projection$1) {
	    return item;
	  }
	  if (item.oProj) {
	    return item.oProj;
	  }
	  return Projection$1(item);
	}
	function proj4$1(fromProj, toProj, coord) {
	  fromProj = checkProj(fromProj);
	  var single = false;
	  var obj;
	  if (typeof toProj === 'undefined') {
	    toProj = fromProj;
	    fromProj = wgs84;
	    single = true;
	  }
	  else if (typeof toProj.x !== 'undefined' || Array.isArray(toProj)) {
	    coord = toProj;
	    toProj = fromProj;
	    fromProj = wgs84;
	    single = true;
	  }
	  toProj = checkProj(toProj);
	  if (coord) {
	    return transformer(fromProj, toProj, coord);
	  }
	  else {
	    obj = {
	      forward: function(coords) {
	        return transformer(fromProj, toProj, coords);
	      },
	      inverse: function(coords) {
	        return transformer(toProj, fromProj, coords);
	      }
	    };
	    if (single) {
	      obj.oProj = toProj;
	    }
	    return obj;
	  }
	}

	/**
	 * UTM zones are grouped, and assigned to one of a group of 6
	 * sets.
	 *
	 * {int} @private
	 */
	var NUM_100K_SETS = 6;

	/**
	 * The column letters (for easting) of the lower left value, per
	 * set.
	 *
	 * {string} @private
	 */
	var SET_ORIGIN_COLUMN_LETTERS = 'AJSAJS';

	/**
	 * The row letters (for northing) of the lower left value, per
	 * set.
	 *
	 * {string} @private
	 */
	var SET_ORIGIN_ROW_LETTERS = 'AFAFAF';

	var A = 65; // A
	var I = 73; // I
	var O = 79; // O
	var V = 86; // V
	var Z = 90; // Z
	var mgrs = {
	  forward: forward$1,
	  inverse: inverse$1,
	  toPoint: toPoint$1
	};
	/**
	 * Conversion of lat/lon to MGRS.
	 *
	 * @param {object} ll Object literal with lat and lon properties on a
	 *     WGS84 ellipsoid.
	 * @param {int} accuracy Accuracy in digits (5 for 1 m, 4 for 10 m, 3 for
	 *      100 m, 2 for 1000 m or 1 for 10000 m). Optional, default is 5.
	 * @return {string} the MGRS string for the given location and accuracy.
	 */
	function forward$1(ll, accuracy) {
	  accuracy = accuracy || 5; // default accuracy 1m
	  return encode(LLtoUTM({
	    lat: ll[1],
	    lon: ll[0]
	  }), accuracy);
	}

	/**
	 * Conversion of MGRS to lat/lon.
	 *
	 * @param {string} mgrs MGRS string.
	 * @return {array} An array with left (longitude), bottom (latitude), right
	 *     (longitude) and top (latitude) values in WGS84, representing the
	 *     bounding box for the provided MGRS reference.
	 */
	function inverse$1(mgrs) {
	  var bbox = UTMtoLL(decode(mgrs.toUpperCase()));
	  if (bbox.lat && bbox.lon) {
	    return [bbox.lon, bbox.lat, bbox.lon, bbox.lat];
	  }
	  return [bbox.left, bbox.bottom, bbox.right, bbox.top];
	}

	function toPoint$1(mgrs) {
	  var bbox = UTMtoLL(decode(mgrs.toUpperCase()));
	  if (bbox.lat && bbox.lon) {
	    return [bbox.lon, bbox.lat];
	  }
	  return [(bbox.left + bbox.right) / 2, (bbox.top + bbox.bottom) / 2];
	}
	/**
	 * Conversion from degrees to radians.
	 *
	 * @private
	 * @param {number} deg the angle in degrees.
	 * @return {number} the angle in radians.
	 */
	function degToRad(deg) {
	  return (deg * (Math.PI / 180.0));
	}

	/**
	 * Conversion from radians to degrees.
	 *
	 * @private
	 * @param {number} rad the angle in radians.
	 * @return {number} the angle in degrees.
	 */
	function radToDeg(rad) {
	  return (180.0 * (rad / Math.PI));
	}

	/**
	 * Converts a set of Longitude and Latitude co-ordinates to UTM
	 * using the WGS84 ellipsoid.
	 *
	 * @private
	 * @param {object} ll Object literal with lat and lon properties
	 *     representing the WGS84 coordinate to be converted.
	 * @return {object} Object literal containing the UTM value with easting,
	 *     northing, zoneNumber and zoneLetter properties, and an optional
	 *     accuracy property in digits. Returns null if the conversion failed.
	 */
	function LLtoUTM(ll) {
	  var Lat = ll.lat;
	  var Long = ll.lon;
	  var a = 6378137.0; //ellip.radius;
	  var eccSquared = 0.00669438; //ellip.eccsq;
	  var k0 = 0.9996;
	  var LongOrigin;
	  var eccPrimeSquared;
	  var N, T, C, A, M;
	  var LatRad = degToRad(Lat);
	  var LongRad = degToRad(Long);
	  var LongOriginRad;
	  var ZoneNumber;
	  // (int)
	  ZoneNumber = Math.floor((Long + 180) / 6) + 1;

	  //Make sure the longitude 180.00 is in Zone 60
	  if (Long === 180) {
	    ZoneNumber = 60;
	  }

	  // Special zone for Norway
	  if (Lat >= 56.0 && Lat < 64.0 && Long >= 3.0 && Long < 12.0) {
	    ZoneNumber = 32;
	  }

	  // Special zones for Svalbard
	  if (Lat >= 72.0 && Lat < 84.0) {
	    if (Long >= 0.0 && Long < 9.0) {
	      ZoneNumber = 31;
	    }
	    else if (Long >= 9.0 && Long < 21.0) {
	      ZoneNumber = 33;
	    }
	    else if (Long >= 21.0 && Long < 33.0) {
	      ZoneNumber = 35;
	    }
	    else if (Long >= 33.0 && Long < 42.0) {
	      ZoneNumber = 37;
	    }
	  }

	  LongOrigin = (ZoneNumber - 1) * 6 - 180 + 3; //+3 puts origin
	  // in middle of
	  // zone
	  LongOriginRad = degToRad(LongOrigin);

	  eccPrimeSquared = (eccSquared) / (1 - eccSquared);

	  N = a / Math.sqrt(1 - eccSquared * Math.sin(LatRad) * Math.sin(LatRad));
	  T = Math.tan(LatRad) * Math.tan(LatRad);
	  C = eccPrimeSquared * Math.cos(LatRad) * Math.cos(LatRad);
	  A = Math.cos(LatRad) * (LongRad - LongOriginRad);

	  M = a * ((1 - eccSquared / 4 - 3 * eccSquared * eccSquared / 64 - 5 * eccSquared * eccSquared * eccSquared / 256) * LatRad - (3 * eccSquared / 8 + 3 * eccSquared * eccSquared / 32 + 45 * eccSquared * eccSquared * eccSquared / 1024) * Math.sin(2 * LatRad) + (15 * eccSquared * eccSquared / 256 + 45 * eccSquared * eccSquared * eccSquared / 1024) * Math.sin(4 * LatRad) - (35 * eccSquared * eccSquared * eccSquared / 3072) * Math.sin(6 * LatRad));

	  var UTMEasting = (k0 * N * (A + (1 - T + C) * A * A * A / 6.0 + (5 - 18 * T + T * T + 72 * C - 58 * eccPrimeSquared) * A * A * A * A * A / 120.0) + 500000.0);

	  var UTMNorthing = (k0 * (M + N * Math.tan(LatRad) * (A * A / 2 + (5 - T + 9 * C + 4 * C * C) * A * A * A * A / 24.0 + (61 - 58 * T + T * T + 600 * C - 330 * eccPrimeSquared) * A * A * A * A * A * A / 720.0)));
	  if (Lat < 0.0) {
	    UTMNorthing += 10000000.0; //10000000 meter offset for
	    // southern hemisphere
	  }

	  return {
	    northing: Math.round(UTMNorthing),
	    easting: Math.round(UTMEasting),
	    zoneNumber: ZoneNumber,
	    zoneLetter: getLetterDesignator(Lat)
	  };
	}

	/**
	 * Converts UTM coords to lat/long, using the WGS84 ellipsoid. This is a convenience
	 * class where the Zone can be specified as a single string eg."60N" which
	 * is then broken down into the ZoneNumber and ZoneLetter.
	 *
	 * @private
	 * @param {object} utm An object literal with northing, easting, zoneNumber
	 *     and zoneLetter properties. If an optional accuracy property is
	 *     provided (in meters), a bounding box will be returned instead of
	 *     latitude and longitude.
	 * @return {object} An object literal containing either lat and lon values
	 *     (if no accuracy was provided), or top, right, bottom and left values
	 *     for the bounding box calculated according to the provided accuracy.
	 *     Returns null if the conversion failed.
	 */
	function UTMtoLL(utm) {

	  var UTMNorthing = utm.northing;
	  var UTMEasting = utm.easting;
	  var zoneLetter = utm.zoneLetter;
	  var zoneNumber = utm.zoneNumber;
	  // check the ZoneNummber is valid
	  if (zoneNumber < 0 || zoneNumber > 60) {
	    return null;
	  }

	  var k0 = 0.9996;
	  var a = 6378137.0; //ellip.radius;
	  var eccSquared = 0.00669438; //ellip.eccsq;
	  var eccPrimeSquared;
	  var e1 = (1 - Math.sqrt(1 - eccSquared)) / (1 + Math.sqrt(1 - eccSquared));
	  var N1, T1, C1, R1, D, M;
	  var LongOrigin;
	  var mu, phi1Rad;

	  // remove 500,000 meter offset for longitude
	  var x = UTMEasting - 500000.0;
	  var y = UTMNorthing;

	  // We must know somehow if we are in the Northern or Southern
	  // hemisphere, this is the only time we use the letter So even
	  // if the Zone letter isn't exactly correct it should indicate
	  // the hemisphere correctly
	  if (zoneLetter < 'N') {
	    y -= 10000000.0; // remove 10,000,000 meter offset used
	    // for southern hemisphere
	  }

	  // There are 60 zones with zone 1 being at West -180 to -174
	  LongOrigin = (zoneNumber - 1) * 6 - 180 + 3; // +3 puts origin
	  // in middle of
	  // zone

	  eccPrimeSquared = (eccSquared) / (1 - eccSquared);

	  M = y / k0;
	  mu = M / (a * (1 - eccSquared / 4 - 3 * eccSquared * eccSquared / 64 - 5 * eccSquared * eccSquared * eccSquared / 256));

	  phi1Rad = mu + (3 * e1 / 2 - 27 * e1 * e1 * e1 / 32) * Math.sin(2 * mu) + (21 * e1 * e1 / 16 - 55 * e1 * e1 * e1 * e1 / 32) * Math.sin(4 * mu) + (151 * e1 * e1 * e1 / 96) * Math.sin(6 * mu);
	  // double phi1 = ProjMath.radToDeg(phi1Rad);

	  N1 = a / Math.sqrt(1 - eccSquared * Math.sin(phi1Rad) * Math.sin(phi1Rad));
	  T1 = Math.tan(phi1Rad) * Math.tan(phi1Rad);
	  C1 = eccPrimeSquared * Math.cos(phi1Rad) * Math.cos(phi1Rad);
	  R1 = a * (1 - eccSquared) / Math.pow(1 - eccSquared * Math.sin(phi1Rad) * Math.sin(phi1Rad), 1.5);
	  D = x / (N1 * k0);

	  var lat = phi1Rad - (N1 * Math.tan(phi1Rad) / R1) * (D * D / 2 - (5 + 3 * T1 + 10 * C1 - 4 * C1 * C1 - 9 * eccPrimeSquared) * D * D * D * D / 24 + (61 + 90 * T1 + 298 * C1 + 45 * T1 * T1 - 252 * eccPrimeSquared - 3 * C1 * C1) * D * D * D * D * D * D / 720);
	  lat = radToDeg(lat);

	  var lon = (D - (1 + 2 * T1 + C1) * D * D * D / 6 + (5 - 2 * C1 + 28 * T1 - 3 * C1 * C1 + 8 * eccPrimeSquared + 24 * T1 * T1) * D * D * D * D * D / 120) / Math.cos(phi1Rad);
	  lon = LongOrigin + radToDeg(lon);

	  var result;
	  if (utm.accuracy) {
	    var topRight = UTMtoLL({
	      northing: utm.northing + utm.accuracy,
	      easting: utm.easting + utm.accuracy,
	      zoneLetter: utm.zoneLetter,
	      zoneNumber: utm.zoneNumber
	    });
	    result = {
	      top: topRight.lat,
	      right: topRight.lon,
	      bottom: lat,
	      left: lon
	    };
	  }
	  else {
	    result = {
	      lat: lat,
	      lon: lon
	    };
	  }
	  return result;
	}

	/**
	 * Calculates the MGRS letter designator for the given latitude.
	 *
	 * @private
	 * @param {number} lat The latitude in WGS84 to get the letter designator
	 *     for.
	 * @return {char} The letter designator.
	 */
	function getLetterDesignator(lat) {
	  //This is here as an error flag to show that the Latitude is
	  //outside MGRS limits
	  var LetterDesignator = 'Z';

	  if ((84 >= lat) && (lat >= 72)) {
	    LetterDesignator = 'X';
	  }
	  else if ((72 > lat) && (lat >= 64)) {
	    LetterDesignator = 'W';
	  }
	  else if ((64 > lat) && (lat >= 56)) {
	    LetterDesignator = 'V';
	  }
	  else if ((56 > lat) && (lat >= 48)) {
	    LetterDesignator = 'U';
	  }
	  else if ((48 > lat) && (lat >= 40)) {
	    LetterDesignator = 'T';
	  }
	  else if ((40 > lat) && (lat >= 32)) {
	    LetterDesignator = 'S';
	  }
	  else if ((32 > lat) && (lat >= 24)) {
	    LetterDesignator = 'R';
	  }
	  else if ((24 > lat) && (lat >= 16)) {
	    LetterDesignator = 'Q';
	  }
	  else if ((16 > lat) && (lat >= 8)) {
	    LetterDesignator = 'P';
	  }
	  else if ((8 > lat) && (lat >= 0)) {
	    LetterDesignator = 'N';
	  }
	  else if ((0 > lat) && (lat >= -8)) {
	    LetterDesignator = 'M';
	  }
	  else if ((-8 > lat) && (lat >= -16)) {
	    LetterDesignator = 'L';
	  }
	  else if ((-16 > lat) && (lat >= -24)) {
	    LetterDesignator = 'K';
	  }
	  else if ((-24 > lat) && (lat >= -32)) {
	    LetterDesignator = 'J';
	  }
	  else if ((-32 > lat) && (lat >= -40)) {
	    LetterDesignator = 'H';
	  }
	  else if ((-40 > lat) && (lat >= -48)) {
	    LetterDesignator = 'G';
	  }
	  else if ((-48 > lat) && (lat >= -56)) {
	    LetterDesignator = 'F';
	  }
	  else if ((-56 > lat) && (lat >= -64)) {
	    LetterDesignator = 'E';
	  }
	  else if ((-64 > lat) && (lat >= -72)) {
	    LetterDesignator = 'D';
	  }
	  else if ((-72 > lat) && (lat >= -80)) {
	    LetterDesignator = 'C';
	  }
	  return LetterDesignator;
	}

	/**
	 * Encodes a UTM location as MGRS string.
	 *
	 * @private
	 * @param {object} utm An object literal with easting, northing,
	 *     zoneLetter, zoneNumber
	 * @param {number} accuracy Accuracy in digits (1-5).
	 * @return {string} MGRS string for the given UTM location.
	 */
	function encode(utm, accuracy) {
	  // prepend with leading zeroes
	  var seasting = "00000" + utm.easting,
	    snorthing = "00000" + utm.northing;

	  return utm.zoneNumber + utm.zoneLetter + get100kID(utm.easting, utm.northing, utm.zoneNumber) + seasting.substr(seasting.length - 5, accuracy) + snorthing.substr(snorthing.length - 5, accuracy);
	}

	/**
	 * Get the two letter 100k designator for a given UTM easting,
	 * northing and zone number value.
	 *
	 * @private
	 * @param {number} easting
	 * @param {number} northing
	 * @param {number} zoneNumber
	 * @return the two letter 100k designator for the given UTM location.
	 */
	function get100kID(easting, northing, zoneNumber) {
	  var setParm = get100kSetForZone(zoneNumber);
	  var setColumn = Math.floor(easting / 100000);
	  var setRow = Math.floor(northing / 100000) % 20;
	  return getLetter100kID(setColumn, setRow, setParm);
	}

	/**
	 * Given a UTM zone number, figure out the MGRS 100K set it is in.
	 *
	 * @private
	 * @param {number} i An UTM zone number.
	 * @return {number} the 100k set the UTM zone is in.
	 */
	function get100kSetForZone(i) {
	  var setParm = i % NUM_100K_SETS;
	  if (setParm === 0) {
	    setParm = NUM_100K_SETS;
	  }

	  return setParm;
	}

	/**
	 * Get the two-letter MGRS 100k designator given information
	 * translated from the UTM northing, easting and zone number.
	 *
	 * @private
	 * @param {number} column the column index as it relates to the MGRS
	 *        100k set spreadsheet, created from the UTM easting.
	 *        Values are 1-8.
	 * @param {number} row the row index as it relates to the MGRS 100k set
	 *        spreadsheet, created from the UTM northing value. Values
	 *        are from 0-19.
	 * @param {number} parm the set block, as it relates to the MGRS 100k set
	 *        spreadsheet, created from the UTM zone. Values are from
	 *        1-60.
	 * @return two letter MGRS 100k code.
	 */
	function getLetter100kID(column, row, parm) {
	  // colOrigin and rowOrigin are the letters at the origin of the set
	  var index = parm - 1;
	  var colOrigin = SET_ORIGIN_COLUMN_LETTERS.charCodeAt(index);
	  var rowOrigin = SET_ORIGIN_ROW_LETTERS.charCodeAt(index);

	  // colInt and rowInt are the letters to build to return
	  var colInt = colOrigin + column - 1;
	  var rowInt = rowOrigin + row;
	  var rollover = false;

	  if (colInt > Z) {
	    colInt = colInt - Z + A - 1;
	    rollover = true;
	  }

	  if (colInt === I || (colOrigin < I && colInt > I) || ((colInt > I || colOrigin < I) && rollover)) {
	    colInt++;
	  }

	  if (colInt === O || (colOrigin < O && colInt > O) || ((colInt > O || colOrigin < O) && rollover)) {
	    colInt++;

	    if (colInt === I) {
	      colInt++;
	    }
	  }

	  if (colInt > Z) {
	    colInt = colInt - Z + A - 1;
	  }

	  if (rowInt > V) {
	    rowInt = rowInt - V + A - 1;
	    rollover = true;
	  }
	  else {
	    rollover = false;
	  }

	  if (((rowInt === I) || ((rowOrigin < I) && (rowInt > I))) || (((rowInt > I) || (rowOrigin < I)) && rollover)) {
	    rowInt++;
	  }

	  if (((rowInt === O) || ((rowOrigin < O) && (rowInt > O))) || (((rowInt > O) || (rowOrigin < O)) && rollover)) {
	    rowInt++;

	    if (rowInt === I) {
	      rowInt++;
	    }
	  }

	  if (rowInt > V) {
	    rowInt = rowInt - V + A - 1;
	  }

	  var twoLetter = String.fromCharCode(colInt) + String.fromCharCode(rowInt);
	  return twoLetter;
	}

	/**
	 * Decode the UTM parameters from a MGRS string.
	 *
	 * @private
	 * @param {string} mgrsString an UPPERCASE coordinate string is expected.
	 * @return {object} An object literal with easting, northing, zoneLetter,
	 *     zoneNumber and accuracy (in meters) properties.
	 */
	function decode(mgrsString) {

	  if (mgrsString && mgrsString.length === 0) {
	    throw ("MGRSPoint coverting from nothing");
	  }

	  var length = mgrsString.length;

	  var hunK = null;
	  var sb = "";
	  var testChar;
	  var i = 0;

	  // get Zone number
	  while (!(/[A-Z]/).test(testChar = mgrsString.charAt(i))) {
	    if (i >= 2) {
	      throw ("MGRSPoint bad conversion from: " + mgrsString);
	    }
	    sb += testChar;
	    i++;
	  }

	  var zoneNumber = parseInt(sb, 10);

	  if (i === 0 || i + 3 > length) {
	    // A good MGRS string has to be 4-5 digits long,
	    // ##AAA/#AAA at least.
	    throw ("MGRSPoint bad conversion from: " + mgrsString);
	  }

	  var zoneLetter = mgrsString.charAt(i++);

	  // Should we check the zone letter here? Why not.
	  if (zoneLetter <= 'A' || zoneLetter === 'B' || zoneLetter === 'Y' || zoneLetter >= 'Z' || zoneLetter === 'I' || zoneLetter === 'O') {
	    throw ("MGRSPoint zone letter " + zoneLetter + " not handled: " + mgrsString);
	  }

	  hunK = mgrsString.substring(i, i += 2);

	  var set = get100kSetForZone(zoneNumber);

	  var east100k = getEastingFromChar(hunK.charAt(0), set);
	  var north100k = getNorthingFromChar(hunK.charAt(1), set);

	  // We have a bug where the northing may be 2000000 too low.
	  // How
	  // do we know when to roll over?

	  while (north100k < getMinNorthing(zoneLetter)) {
	    north100k += 2000000;
	  }

	  // calculate the char index for easting/northing separator
	  var remainder = length - i;

	  if (remainder % 2 !== 0) {
	    throw ("MGRSPoint has to have an even number \nof digits after the zone letter and two 100km letters - front \nhalf for easting meters, second half for \nnorthing meters" + mgrsString);
	  }

	  var sep = remainder / 2;

	  var sepEasting = 0.0;
	  var sepNorthing = 0.0;
	  var accuracyBonus, sepEastingString, sepNorthingString, easting, northing;
	  if (sep > 0) {
	    accuracyBonus = 100000.0 / Math.pow(10, sep);
	    sepEastingString = mgrsString.substring(i, i + sep);
	    sepEasting = parseFloat(sepEastingString) * accuracyBonus;
	    sepNorthingString = mgrsString.substring(i + sep);
	    sepNorthing = parseFloat(sepNorthingString) * accuracyBonus;
	  }

	  easting = sepEasting + east100k;
	  northing = sepNorthing + north100k;

	  return {
	    easting: easting,
	    northing: northing,
	    zoneLetter: zoneLetter,
	    zoneNumber: zoneNumber,
	    accuracy: accuracyBonus
	  };
	}

	/**
	 * Given the first letter from a two-letter MGRS 100k zone, and given the
	 * MGRS table set for the zone number, figure out the easting value that
	 * should be added to the other, secondary easting value.
	 *
	 * @private
	 * @param {char} e The first letter from a two-letter MGRS 100´k zone.
	 * @param {number} set The MGRS table set for the zone number.
	 * @return {number} The easting value for the given letter and set.
	 */
	function getEastingFromChar(e, set) {
	  // colOrigin is the letter at the origin of the set for the
	  // column
	  var curCol = SET_ORIGIN_COLUMN_LETTERS.charCodeAt(set - 1);
	  var eastingValue = 100000.0;
	  var rewindMarker = false;

	  while (curCol !== e.charCodeAt(0)) {
	    curCol++;
	    if (curCol === I) {
	      curCol++;
	    }
	    if (curCol === O) {
	      curCol++;
	    }
	    if (curCol > Z) {
	      if (rewindMarker) {
	        throw ("Bad character: " + e);
	      }
	      curCol = A;
	      rewindMarker = true;
	    }
	    eastingValue += 100000.0;
	  }

	  return eastingValue;
	}

	/**
	 * Given the second letter from a two-letter MGRS 100k zone, and given the
	 * MGRS table set for the zone number, figure out the northing value that
	 * should be added to the other, secondary northing value. You have to
	 * remember that Northings are determined from the equator, and the vertical
	 * cycle of letters mean a 2000000 additional northing meters. This happens
	 * approx. every 18 degrees of latitude. This method does *NOT* count any
	 * additional northings. You have to figure out how many 2000000 meters need
	 * to be added for the zone letter of the MGRS coordinate.
	 *
	 * @private
	 * @param {char} n Second letter of the MGRS 100k zone
	 * @param {number} set The MGRS table set number, which is dependent on the
	 *     UTM zone number.
	 * @return {number} The northing value for the given letter and set.
	 */
	function getNorthingFromChar(n, set) {

	  if (n > 'V') {
	    throw ("MGRSPoint given invalid Northing " + n);
	  }

	  // rowOrigin is the letter at the origin of the set for the
	  // column
	  var curRow = SET_ORIGIN_ROW_LETTERS.charCodeAt(set - 1);
	  var northingValue = 0.0;
	  var rewindMarker = false;

	  while (curRow !== n.charCodeAt(0)) {
	    curRow++;
	    if (curRow === I) {
	      curRow++;
	    }
	    if (curRow === O) {
	      curRow++;
	    }
	    // fixing a bug making whole application hang in this loop
	    // when 'n' is a wrong character
	    if (curRow > V) {
	      if (rewindMarker) { // making sure that this loop ends
	        throw ("Bad character: " + n);
	      }
	      curRow = A;
	      rewindMarker = true;
	    }
	    northingValue += 100000.0;
	  }

	  return northingValue;
	}

	/**
	 * The function getMinNorthing returns the minimum northing value of a MGRS
	 * zone.
	 *
	 * Ported from Geotrans' c Lattitude_Band_Value structure table.
	 *
	 * @private
	 * @param {char} zoneLetter The MGRS zone to get the min northing for.
	 * @return {number}
	 */
	function getMinNorthing(zoneLetter) {
	  var northing;
	  switch (zoneLetter) {
	  case 'C':
	    northing = 1100000.0;
	    break;
	  case 'D':
	    northing = 2000000.0;
	    break;
	  case 'E':
	    northing = 2800000.0;
	    break;
	  case 'F':
	    northing = 3700000.0;
	    break;
	  case 'G':
	    northing = 4600000.0;
	    break;
	  case 'H':
	    northing = 5500000.0;
	    break;
	  case 'J':
	    northing = 6400000.0;
	    break;
	  case 'K':
	    northing = 7300000.0;
	    break;
	  case 'L':
	    northing = 8200000.0;
	    break;
	  case 'M':
	    northing = 9100000.0;
	    break;
	  case 'N':
	    northing = 0.0;
	    break;
	  case 'P':
	    northing = 800000.0;
	    break;
	  case 'Q':
	    northing = 1700000.0;
	    break;
	  case 'R':
	    northing = 2600000.0;
	    break;
	  case 'S':
	    northing = 3500000.0;
	    break;
	  case 'T':
	    northing = 4400000.0;
	    break;
	  case 'U':
	    northing = 5300000.0;
	    break;
	  case 'V':
	    northing = 6200000.0;
	    break;
	  case 'W':
	    northing = 7000000.0;
	    break;
	  case 'X':
	    northing = 7900000.0;
	    break;
	  default:
	    northing = -1.0;
	  }
	  if (northing >= 0.0) {
	    return northing;
	  }
	  else {
	    throw ("Invalid zone letter: " + zoneLetter);
	  }

	}

	function Point(x, y, z) {
	  if (!(this instanceof Point)) {
	    return new Point(x, y, z);
	  }
	  if (Array.isArray(x)) {
	    this.x = x[0];
	    this.y = x[1];
	    this.z = x[2] || 0.0;
	  } else if(typeof x === 'object') {
	    this.x = x.x;
	    this.y = x.y;
	    this.z = x.z || 0.0;
	  } else if (typeof x === 'string' && typeof y === 'undefined') {
	    var coords = x.split(',');
	    this.x = parseFloat(coords[0], 10);
	    this.y = parseFloat(coords[1], 10);
	    this.z = parseFloat(coords[2], 10) || 0.0;
	  } else {
	    this.x = x;
	    this.y = y;
	    this.z = z || 0.0;
	  }
	  console.warn('proj4.Point will be removed in version 3, use proj4.toPoint');
	}

	Point.fromMGRS = function(mgrsStr) {
	  return new Point(toPoint$1(mgrsStr));
	};
	Point.prototype.toMGRS = function(accuracy) {
	  return forward$1([this.x, this.y], accuracy);
	};

	var version = "2.4.4";

	var C00 = 1;
	var C02 = 0.25;
	var C04 = 0.046875;
	var C06 = 0.01953125;
	var C08 = 0.01068115234375;
	var C22 = 0.75;
	var C44 = 0.46875;
	var C46 = 0.01302083333333333333;
	var C48 = 0.00712076822916666666;
	var C66 = 0.36458333333333333333;
	var C68 = 0.00569661458333333333;
	var C88 = 0.3076171875;

	var pj_enfn = function(es) {
	  var en = [];
	  en[0] = C00 - es * (C02 + es * (C04 + es * (C06 + es * C08)));
	  en[1] = es * (C22 - es * (C04 + es * (C06 + es * C08)));
	  var t = es * es;
	  en[2] = t * (C44 - es * (C46 + es * C48));
	  t *= es;
	  en[3] = t * (C66 - es * C68);
	  en[4] = t * es * C88;
	  return en;
	};

	var pj_mlfn = function(phi, sphi, cphi, en) {
	  cphi *= sphi;
	  sphi *= sphi;
	  return (en[0] * phi - cphi * (en[1] + sphi * (en[2] + sphi * (en[3] + sphi * en[4]))));
	};

	var MAX_ITER = 20;

	var pj_inv_mlfn = function(arg, es, en) {
	  var k = 1 / (1 - es);
	  var phi = arg;
	  for (var i = MAX_ITER; i; --i) { /* rarely goes over 2 iterations */
	    var s = Math.sin(phi);
	    var t = 1 - es * s * s;
	    //t = this.pj_mlfn(phi, s, Math.cos(phi), en) - arg;
	    //phi -= t * (t * Math.sqrt(t)) * k;
	    t = (pj_mlfn(phi, s, Math.cos(phi), en) - arg) * (t * Math.sqrt(t)) * k;
	    phi -= t;
	    if (Math.abs(t) < EPSLN) {
	      return phi;
	    }
	  }
	  //..reportError("cass:pj_inv_mlfn: Convergence error");
	  return phi;
	};

	// Heavily based on this tmerc projection implementation
	// https://github.com/mbloch/mapshaper-proj/blob/master/src/projections/tmerc.js

	function init$2() {
	  this.x0 = this.x0 !== undefined ? this.x0 : 0;
	  this.y0 = this.y0 !== undefined ? this.y0 : 0;
	  this.long0 = this.long0 !== undefined ? this.long0 : 0;
	  this.lat0 = this.lat0 !== undefined ? this.lat0 : 0;

	  if (this.es) {
	    this.en = pj_enfn(this.es);
	    this.ml0 = pj_mlfn(this.lat0, Math.sin(this.lat0), Math.cos(this.lat0), this.en);
	  }
	}

	/**
	    Transverse Mercator Forward  - long/lat to x/y
	    long/lat in radians
	  */
	function forward$2(p) {
	  var lon = p.x;
	  var lat = p.y;

	  var delta_lon = adjust_lon(lon - this.long0);
	  var con;
	  var x, y;
	  var sin_phi = Math.sin(lat);
	  var cos_phi = Math.cos(lat);

	  if (!this.es) {
	    var b = cos_phi * Math.sin(delta_lon);

	    if ((Math.abs(Math.abs(b) - 1)) < EPSLN) {
	      return (93);
	    }
	    else {
	      x = 0.5 * this.a * this.k0 * Math.log((1 + b) / (1 - b)) + this.x0;
	      y = cos_phi * Math.cos(delta_lon) / Math.sqrt(1 - Math.pow(b, 2));
	      b = Math.abs(y);

	      if (b >= 1) {
	        if ((b - 1) > EPSLN) {
	          return (93);
	        }
	        else {
	          y = 0;
	        }
	      }
	      else {
	        y = Math.acos(y);
	      }

	      if (lat < 0) {
	        y = -y;
	      }

	      y = this.a * this.k0 * (y - this.lat0) + this.y0;
	    }
	  }
	  else {
	    var al = cos_phi * delta_lon;
	    var als = Math.pow(al, 2);
	    var c = this.ep2 * Math.pow(cos_phi, 2);
	    var cs = Math.pow(c, 2);
	    var tq = Math.abs(cos_phi) > EPSLN ? Math.tan(lat) : 0;
	    var t = Math.pow(tq, 2);
	    var ts = Math.pow(t, 2);
	    con = 1 - this.es * Math.pow(sin_phi, 2);
	    al = al / Math.sqrt(con);
	    var ml = pj_mlfn(lat, sin_phi, cos_phi, this.en);

	    x = this.a * (this.k0 * al * (1 +
	      als / 6 * (1 - t + c +
	      als / 20 * (5 - 18 * t + ts + 14 * c - 58 * t * c +
	      als / 42 * (61 + 179 * ts - ts * t - 479 * t))))) +
	      this.x0;

	    y = this.a * (this.k0 * (ml - this.ml0 +
	      sin_phi * delta_lon * al / 2 * (1 +
	      als / 12 * (5 - t + 9 * c + 4 * cs +
	      als / 30 * (61 + ts - 58 * t + 270 * c - 330 * t * c +
	      als / 56 * (1385 + 543 * ts - ts * t - 3111 * t)))))) +
	      this.y0;
	  }

	  p.x = x;
	  p.y = y;

	  return p;
	}

	/**
	    Transverse Mercator Inverse  -  x/y to long/lat
	  */
	function inverse$2(p) {
	  var con, phi;
	  var lat, lon;
	  var x = (p.x - this.x0) * (1 / this.a);
	  var y = (p.y - this.y0) * (1 / this.a);

	  if (!this.es) {
	    var f = Math.exp(x / this.k0);
	    var g = 0.5 * (f - 1 / f);
	    var temp = this.lat0 + y / this.k0;
	    var h = Math.cos(temp);
	    con = Math.sqrt((1 - Math.pow(h, 2)) / (1 + Math.pow(g, 2)));
	    lat = Math.asin(con);

	    if (y < 0) {
	      lat = -lat;
	    }

	    if ((g === 0) && (h === 0)) {
	      lon = 0;
	    }
	    else {
	      lon = adjust_lon(Math.atan2(g, h) + this.long0);
	    }
	  }
	  else { // ellipsoidal form
	    con = this.ml0 + y / this.k0;
	    phi = pj_inv_mlfn(con, this.es, this.en);

	    if (Math.abs(phi) < HALF_PI) {
	      var sin_phi = Math.sin(phi);
	      var cos_phi = Math.cos(phi);
	      var tan_phi = Math.abs(cos_phi) > EPSLN ? Math.tan(phi) : 0;
	      var c = this.ep2 * Math.pow(cos_phi, 2);
	      var cs = Math.pow(c, 2);
	      var t = Math.pow(tan_phi, 2);
	      var ts = Math.pow(t, 2);
	      con = 1 - this.es * Math.pow(sin_phi, 2);
	      var d = x * Math.sqrt(con) / this.k0;
	      var ds = Math.pow(d, 2);
	      con = con * tan_phi;

	      lat = phi - (con * ds / (1 - this.es)) * 0.5 * (1 -
	        ds / 12 * (5 + 3 * t - 9 * c * t + c - 4 * cs -
	        ds / 30 * (61 + 90 * t - 252 * c * t + 45 * ts + 46 * c -
	        ds / 56 * (1385 + 3633 * t + 4095 * ts + 1574 * ts * t))));

	      lon = adjust_lon(this.long0 + (d * (1 -
	        ds / 6 * (1 + 2 * t + c -
	        ds / 20 * (5 + 28 * t + 24 * ts + 8 * c * t + 6 * c -
	        ds / 42 * (61 + 662 * t + 1320 * ts + 720 * ts * t)))) / cos_phi));
	    }
	    else {
	      lat = HALF_PI * sign(y);
	      lon = 0;
	    }
	  }

	  p.x = lon;
	  p.y = lat;

	  return p;
	}

	var names$3 = ["Transverse_Mercator", "Transverse Mercator", "tmerc"];
	var tmerc = {
	  init: init$2,
	  forward: forward$2,
	  inverse: inverse$2,
	  names: names$3
	};

	var sinh = function(x) {
	  var r = Math.exp(x);
	  r = (r - 1 / r) / 2;
	  return r;
	};

	var hypot = function(x, y) {
	  x = Math.abs(x);
	  y = Math.abs(y);
	  var a = Math.max(x, y);
	  var b = Math.min(x, y) / (a ? a : 1);

	  return a * Math.sqrt(1 + Math.pow(b, 2));
	};

	var log1py = function(x) {
	  var y = 1 + x;
	  var z = y - 1;

	  return z === 0 ? x : x * Math.log(y) / z;
	};

	var asinhy = function(x) {
	  var y = Math.abs(x);
	  y = log1py(y * (1 + y / (hypot(1, y) + 1)));

	  return x < 0 ? -y : y;
	};

	var gatg = function(pp, B) {
	  var cos_2B = 2 * Math.cos(2 * B);
	  var i = pp.length - 1;
	  var h1 = pp[i];
	  var h2 = 0;
	  var h;

	  while (--i >= 0) {
	    h = -h2 + cos_2B * h1 + pp[i];
	    h2 = h1;
	    h1 = h;
	  }

	  return (B + h * Math.sin(2 * B));
	};

	var clens = function(pp, arg_r) {
	  var r = 2 * Math.cos(arg_r);
	  var i = pp.length - 1;
	  var hr1 = pp[i];
	  var hr2 = 0;
	  var hr;

	  while (--i >= 0) {
	    hr = -hr2 + r * hr1 + pp[i];
	    hr2 = hr1;
	    hr1 = hr;
	  }

	  return Math.sin(arg_r) * hr;
	};

	var cosh = function(x) {
	  var r = Math.exp(x);
	  r = (r + 1 / r) / 2;
	  return r;
	};

	var clens_cmplx = function(pp, arg_r, arg_i) {
	  var sin_arg_r = Math.sin(arg_r);
	  var cos_arg_r = Math.cos(arg_r);
	  var sinh_arg_i = sinh(arg_i);
	  var cosh_arg_i = cosh(arg_i);
	  var r = 2 * cos_arg_r * cosh_arg_i;
	  var i = -2 * sin_arg_r * sinh_arg_i;
	  var j = pp.length - 1;
	  var hr = pp[j];
	  var hi1 = 0;
	  var hr1 = 0;
	  var hi = 0;
	  var hr2;
	  var hi2;

	  while (--j >= 0) {
	    hr2 = hr1;
	    hi2 = hi1;
	    hr1 = hr;
	    hi1 = hi;
	    hr = -hr2 + r * hr1 - i * hi1 + pp[j];
	    hi = -hi2 + i * hr1 + r * hi1;
	  }

	  r = sin_arg_r * cosh_arg_i;
	  i = cos_arg_r * sinh_arg_i;

	  return [r * hr - i * hi, r * hi + i * hr];
	};

	// Heavily based on this etmerc projection implementation
	// https://github.com/mbloch/mapshaper-proj/blob/master/src/projections/etmerc.js

	function init$3() {
	  if (this.es === undefined || this.es <= 0) {
	    throw new Error('incorrect elliptical usage');
	  }

	  this.x0 = this.x0 !== undefined ? this.x0 : 0;
	  this.y0 = this.y0 !== undefined ? this.y0 : 0;
	  this.long0 = this.long0 !== undefined ? this.long0 : 0;
	  this.lat0 = this.lat0 !== undefined ? this.lat0 : 0;

	  this.cgb = [];
	  this.cbg = [];
	  this.utg = [];
	  this.gtu = [];

	  var f = this.es / (1 + Math.sqrt(1 - this.es));
	  var n = f / (2 - f);
	  var np = n;

	  this.cgb[0] = n * (2 + n * (-2 / 3 + n * (-2 + n * (116 / 45 + n * (26 / 45 + n * (-2854 / 675 ))))));
	  this.cbg[0] = n * (-2 + n * ( 2 / 3 + n * ( 4 / 3 + n * (-82 / 45 + n * (32 / 45 + n * (4642 / 4725))))));

	  np = np * n;
	  this.cgb[1] = np * (7 / 3 + n * (-8 / 5 + n * (-227 / 45 + n * (2704 / 315 + n * (2323 / 945)))));
	  this.cbg[1] = np * (5 / 3 + n * (-16 / 15 + n * ( -13 / 9 + n * (904 / 315 + n * (-1522 / 945)))));

	  np = np * n;
	  this.cgb[2] = np * (56 / 15 + n * (-136 / 35 + n * (-1262 / 105 + n * (73814 / 2835))));
	  this.cbg[2] = np * (-26 / 15 + n * (34 / 21 + n * (8 / 5 + n * (-12686 / 2835))));

	  np = np * n;
	  this.cgb[3] = np * (4279 / 630 + n * (-332 / 35 + n * (-399572 / 14175)));
	  this.cbg[3] = np * (1237 / 630 + n * (-12 / 5 + n * ( -24832 / 14175)));

	  np = np * n;
	  this.cgb[4] = np * (4174 / 315 + n * (-144838 / 6237));
	  this.cbg[4] = np * (-734 / 315 + n * (109598 / 31185));

	  np = np * n;
	  this.cgb[5] = np * (601676 / 22275);
	  this.cbg[5] = np * (444337 / 155925);

	  np = Math.pow(n, 2);
	  this.Qn = this.k0 / (1 + n) * (1 + np * (1 / 4 + np * (1 / 64 + np / 256)));

	  this.utg[0] = n * (-0.5 + n * ( 2 / 3 + n * (-37 / 96 + n * ( 1 / 360 + n * (81 / 512 + n * (-96199 / 604800))))));
	  this.gtu[0] = n * (0.5 + n * (-2 / 3 + n * (5 / 16 + n * (41 / 180 + n * (-127 / 288 + n * (7891 / 37800))))));

	  this.utg[1] = np * (-1 / 48 + n * (-1 / 15 + n * (437 / 1440 + n * (-46 / 105 + n * (1118711 / 3870720)))));
	  this.gtu[1] = np * (13 / 48 + n * (-3 / 5 + n * (557 / 1440 + n * (281 / 630 + n * (-1983433 / 1935360)))));

	  np = np * n;
	  this.utg[2] = np * (-17 / 480 + n * (37 / 840 + n * (209 / 4480 + n * (-5569 / 90720 ))));
	  this.gtu[2] = np * (61 / 240 + n * (-103 / 140 + n * (15061 / 26880 + n * (167603 / 181440))));

	  np = np * n;
	  this.utg[3] = np * (-4397 / 161280 + n * (11 / 504 + n * (830251 / 7257600)));
	  this.gtu[3] = np * (49561 / 161280 + n * (-179 / 168 + n * (6601661 / 7257600)));

	  np = np * n;
	  this.utg[4] = np * (-4583 / 161280 + n * (108847 / 3991680));
	  this.gtu[4] = np * (34729 / 80640 + n * (-3418889 / 1995840));

	  np = np * n;
	  this.utg[5] = np * (-20648693 / 638668800);
	  this.gtu[5] = np * (212378941 / 319334400);

	  var Z = gatg(this.cbg, this.lat0);
	  this.Zb = -this.Qn * (Z + clens(this.gtu, 2 * Z));
	}

	function forward$3(p) {
	  var Ce = adjust_lon(p.x - this.long0);
	  var Cn = p.y;

	  Cn = gatg(this.cbg, Cn);
	  var sin_Cn = Math.sin(Cn);
	  var cos_Cn = Math.cos(Cn);
	  var sin_Ce = Math.sin(Ce);
	  var cos_Ce = Math.cos(Ce);

	  Cn = Math.atan2(sin_Cn, cos_Ce * cos_Cn);
	  Ce = Math.atan2(sin_Ce * cos_Cn, hypot(sin_Cn, cos_Cn * cos_Ce));
	  Ce = asinhy(Math.tan(Ce));

	  var tmp = clens_cmplx(this.gtu, 2 * Cn, 2 * Ce);

	  Cn = Cn + tmp[0];
	  Ce = Ce + tmp[1];

	  var x;
	  var y;

	  if (Math.abs(Ce) <= 2.623395162778) {
	    x = this.a * (this.Qn * Ce) + this.x0;
	    y = this.a * (this.Qn * Cn + this.Zb) + this.y0;
	  }
	  else {
	    x = Infinity;
	    y = Infinity;
	  }

	  p.x = x;
	  p.y = y;

	  return p;
	}

	function inverse$3(p) {
	  var Ce = (p.x - this.x0) * (1 / this.a);
	  var Cn = (p.y - this.y0) * (1 / this.a);

	  Cn = (Cn - this.Zb) / this.Qn;
	  Ce = Ce / this.Qn;

	  var lon;
	  var lat;

	  if (Math.abs(Ce) <= 2.623395162778) {
	    var tmp = clens_cmplx(this.utg, 2 * Cn, 2 * Ce);

	    Cn = Cn + tmp[0];
	    Ce = Ce + tmp[1];
	    Ce = Math.atan(sinh(Ce));

	    var sin_Cn = Math.sin(Cn);
	    var cos_Cn = Math.cos(Cn);
	    var sin_Ce = Math.sin(Ce);
	    var cos_Ce = Math.cos(Ce);

	    Cn = Math.atan2(sin_Cn * cos_Ce, hypot(sin_Ce, cos_Ce * cos_Cn));
	    Ce = Math.atan2(sin_Ce, cos_Ce * cos_Cn);

	    lon = adjust_lon(Ce + this.long0);
	    lat = gatg(this.cgb, Cn);
	  }
	  else {
	    lon = Infinity;
	    lat = Infinity;
	  }

	  p.x = lon;
	  p.y = lat;

	  return p;
	}

	var names$4 = ["Extended_Transverse_Mercator", "Extended Transverse Mercator", "etmerc"];
	var etmerc = {
	  init: init$3,
	  forward: forward$3,
	  inverse: inverse$3,
	  names: names$4
	};

	var adjust_zone = function(zone, lon) {
	  if (zone === undefined) {
	    zone = Math.floor((adjust_lon(lon) + Math.PI) * 30 / Math.PI) + 1;

	    if (zone < 0) {
	      return 0;
	    } else if (zone > 60) {
	      return 60;
	    }
	  }
	  return zone;
	};

	var dependsOn = 'etmerc';
	function init$4() {
	  var zone = adjust_zone(this.zone, this.long0);
	  if (zone === undefined) {
	    throw new Error('unknown utm zone');
	  }
	  this.lat0 = 0;
	  this.long0 =  ((6 * Math.abs(zone)) - 183) * D2R;
	  this.x0 = 500000;
	  this.y0 = this.utmSouth ? 10000000 : 0;
	  this.k0 = 0.9996;

	  etmerc.init.apply(this);
	  this.forward = etmerc.forward;
	  this.inverse = etmerc.inverse;
	}

	var names$5 = ["Universal Transverse Mercator System", "utm"];
	var utm = {
	  init: init$4,
	  names: names$5,
	  dependsOn: dependsOn
	};

	var srat = function(esinp, exp) {
	  return (Math.pow((1 - esinp) / (1 + esinp), exp));
	};

	var MAX_ITER$1 = 20;
	function init$6() {
	  var sphi = Math.sin(this.lat0);
	  var cphi = Math.cos(this.lat0);
	  cphi *= cphi;
	  this.rc = Math.sqrt(1 - this.es) / (1 - this.es * sphi * sphi);
	  this.C = Math.sqrt(1 + this.es * cphi * cphi / (1 - this.es));
	  this.phic0 = Math.asin(sphi / this.C);
	  this.ratexp = 0.5 * this.C * this.e;
	  this.K = Math.tan(0.5 * this.phic0 + FORTPI) / (Math.pow(Math.tan(0.5 * this.lat0 + FORTPI), this.C) * srat(this.e * sphi, this.ratexp));
	}

	function forward$5(p) {
	  var lon = p.x;
	  var lat = p.y;

	  p.y = 2 * Math.atan(this.K * Math.pow(Math.tan(0.5 * lat + FORTPI), this.C) * srat(this.e * Math.sin(lat), this.ratexp)) - HALF_PI;
	  p.x = this.C * lon;
	  return p;
	}

	function inverse$5(p) {
	  var DEL_TOL = 1e-14;
	  var lon = p.x / this.C;
	  var lat = p.y;
	  var num = Math.pow(Math.tan(0.5 * lat + FORTPI) / this.K, 1 / this.C);
	  for (var i = MAX_ITER$1; i > 0; --i) {
	    lat = 2 * Math.atan(num * srat(this.e * Math.sin(p.y), - 0.5 * this.e)) - HALF_PI;
	    if (Math.abs(lat - p.y) < DEL_TOL) {
	      break;
	    }
	    p.y = lat;
	  }
	  /* convergence failed */
	  if (!i) {
	    return null;
	  }
	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$7 = ["gauss"];
	var gauss = {
	  init: init$6,
	  forward: forward$5,
	  inverse: inverse$5,
	  names: names$7
	};

	function init$5() {
	  gauss.init.apply(this);
	  if (!this.rc) {
	    return;
	  }
	  this.sinc0 = Math.sin(this.phic0);
	  this.cosc0 = Math.cos(this.phic0);
	  this.R2 = 2 * this.rc;
	  if (!this.title) {
	    this.title = "Oblique Stereographic Alternative";
	  }
	}

	function forward$4(p) {
	  var sinc, cosc, cosl, k;
	  p.x = adjust_lon(p.x - this.long0);
	  gauss.forward.apply(this, [p]);
	  sinc = Math.sin(p.y);
	  cosc = Math.cos(p.y);
	  cosl = Math.cos(p.x);
	  k = this.k0 * this.R2 / (1 + this.sinc0 * sinc + this.cosc0 * cosc * cosl);
	  p.x = k * cosc * Math.sin(p.x);
	  p.y = k * (this.cosc0 * sinc - this.sinc0 * cosc * cosl);
	  p.x = this.a * p.x + this.x0;
	  p.y = this.a * p.y + this.y0;
	  return p;
	}

	function inverse$4(p) {
	  var sinc, cosc, lon, lat, rho;
	  p.x = (p.x - this.x0) / this.a;
	  p.y = (p.y - this.y0) / this.a;

	  p.x /= this.k0;
	  p.y /= this.k0;
	  if ((rho = Math.sqrt(p.x * p.x + p.y * p.y))) {
	    var c = 2 * Math.atan2(rho, this.R2);
	    sinc = Math.sin(c);
	    cosc = Math.cos(c);
	    lat = Math.asin(cosc * this.sinc0 + p.y * sinc * this.cosc0 / rho);
	    lon = Math.atan2(p.x * sinc, rho * this.cosc0 * cosc - p.y * this.sinc0 * sinc);
	  }
	  else {
	    lat = this.phic0;
	    lon = 0;
	  }

	  p.x = lon;
	  p.y = lat;
	  gauss.inverse.apply(this, [p]);
	  p.x = adjust_lon(p.x + this.long0);
	  return p;
	}

	var names$6 = ["Stereographic_North_Pole", "Oblique_Stereographic", "Polar_Stereographic", "sterea","Oblique Stereographic Alternative"];
	var sterea = {
	  init: init$5,
	  forward: forward$4,
	  inverse: inverse$4,
	  names: names$6
	};

	function ssfn_(phit, sinphi, eccen) {
	  sinphi *= eccen;
	  return (Math.tan(0.5 * (HALF_PI + phit)) * Math.pow((1 - sinphi) / (1 + sinphi), 0.5 * eccen));
	}

	function init$7() {
	  this.coslat0 = Math.cos(this.lat0);
	  this.sinlat0 = Math.sin(this.lat0);
	  if (this.sphere) {
	    if (this.k0 === 1 && !isNaN(this.lat_ts) && Math.abs(this.coslat0) <= EPSLN) {
	      this.k0 = 0.5 * (1 + sign(this.lat0) * Math.sin(this.lat_ts));
	    }
	  }
	  else {
	    if (Math.abs(this.coslat0) <= EPSLN) {
	      if (this.lat0 > 0) {
	        //North pole
	        //trace('stere:north pole');
	        this.con = 1;
	      }
	      else {
	        //South pole
	        //trace('stere:south pole');
	        this.con = -1;
	      }
	    }
	    this.cons = Math.sqrt(Math.pow(1 + this.e, 1 + this.e) * Math.pow(1 - this.e, 1 - this.e));
	    if (this.k0 === 1 && !isNaN(this.lat_ts) && Math.abs(this.coslat0) <= EPSLN) {
	      this.k0 = 0.5 * this.cons * msfnz(this.e, Math.sin(this.lat_ts), Math.cos(this.lat_ts)) / tsfnz(this.e, this.con * this.lat_ts, this.con * Math.sin(this.lat_ts));
	    }
	    this.ms1 = msfnz(this.e, this.sinlat0, this.coslat0);
	    this.X0 = 2 * Math.atan(this.ssfn_(this.lat0, this.sinlat0, this.e)) - HALF_PI;
	    this.cosX0 = Math.cos(this.X0);
	    this.sinX0 = Math.sin(this.X0);
	  }
	}

	// Stereographic forward equations--mapping lat,long to x,y
	function forward$6(p) {
	  var lon = p.x;
	  var lat = p.y;
	  var sinlat = Math.sin(lat);
	  var coslat = Math.cos(lat);
	  var A, X, sinX, cosX, ts, rh;
	  var dlon = adjust_lon(lon - this.long0);

	  if (Math.abs(Math.abs(lon - this.long0) - Math.PI) <= EPSLN && Math.abs(lat + this.lat0) <= EPSLN) {
	    //case of the origine point
	    //trace('stere:this is the origin point');
	    p.x = NaN;
	    p.y = NaN;
	    return p;
	  }
	  if (this.sphere) {
	    //trace('stere:sphere case');
	    A = 2 * this.k0 / (1 + this.sinlat0 * sinlat + this.coslat0 * coslat * Math.cos(dlon));
	    p.x = this.a * A * coslat * Math.sin(dlon) + this.x0;
	    p.y = this.a * A * (this.coslat0 * sinlat - this.sinlat0 * coslat * Math.cos(dlon)) + this.y0;
	    return p;
	  }
	  else {
	    X = 2 * Math.atan(this.ssfn_(lat, sinlat, this.e)) - HALF_PI;
	    cosX = Math.cos(X);
	    sinX = Math.sin(X);
	    if (Math.abs(this.coslat0) <= EPSLN) {
	      ts = tsfnz(this.e, lat * this.con, this.con * sinlat);
	      rh = 2 * this.a * this.k0 * ts / this.cons;
	      p.x = this.x0 + rh * Math.sin(lon - this.long0);
	      p.y = this.y0 - this.con * rh * Math.cos(lon - this.long0);
	      //trace(p.toString());
	      return p;
	    }
	    else if (Math.abs(this.sinlat0) < EPSLN) {
	      //Eq
	      //trace('stere:equateur');
	      A = 2 * this.a * this.k0 / (1 + cosX * Math.cos(dlon));
	      p.y = A * sinX;
	    }
	    else {
	      //other case
	      //trace('stere:normal case');
	      A = 2 * this.a * this.k0 * this.ms1 / (this.cosX0 * (1 + this.sinX0 * sinX + this.cosX0 * cosX * Math.cos(dlon)));
	      p.y = A * (this.cosX0 * sinX - this.sinX0 * cosX * Math.cos(dlon)) + this.y0;
	    }
	    p.x = A * cosX * Math.sin(dlon) + this.x0;
	  }
	  //trace(p.toString());
	  return p;
	}

	//* Stereographic inverse equations--mapping x,y to lat/long
	function inverse$6(p) {
	  p.x -= this.x0;
	  p.y -= this.y0;
	  var lon, lat, ts, ce, Chi;
	  var rh = Math.sqrt(p.x * p.x + p.y * p.y);
	  if (this.sphere) {
	    var c = 2 * Math.atan(rh / (0.5 * this.a * this.k0));
	    lon = this.long0;
	    lat = this.lat0;
	    if (rh <= EPSLN) {
	      p.x = lon;
	      p.y = lat;
	      return p;
	    }
	    lat = Math.asin(Math.cos(c) * this.sinlat0 + p.y * Math.sin(c) * this.coslat0 / rh);
	    if (Math.abs(this.coslat0) < EPSLN) {
	      if (this.lat0 > 0) {
	        lon = adjust_lon(this.long0 + Math.atan2(p.x, - 1 * p.y));
	      }
	      else {
	        lon = adjust_lon(this.long0 + Math.atan2(p.x, p.y));
	      }
	    }
	    else {
	      lon = adjust_lon(this.long0 + Math.atan2(p.x * Math.sin(c), rh * this.coslat0 * Math.cos(c) - p.y * this.sinlat0 * Math.sin(c)));
	    }
	    p.x = lon;
	    p.y = lat;
	    return p;
	  }
	  else {
	    if (Math.abs(this.coslat0) <= EPSLN) {
	      if (rh <= EPSLN) {
	        lat = this.lat0;
	        lon = this.long0;
	        p.x = lon;
	        p.y = lat;
	        //trace(p.toString());
	        return p;
	      }
	      p.x *= this.con;
	      p.y *= this.con;
	      ts = rh * this.cons / (2 * this.a * this.k0);
	      lat = this.con * phi2z(this.e, ts);
	      lon = this.con * adjust_lon(this.con * this.long0 + Math.atan2(p.x, - 1 * p.y));
	    }
	    else {
	      ce = 2 * Math.atan(rh * this.cosX0 / (2 * this.a * this.k0 * this.ms1));
	      lon = this.long0;
	      if (rh <= EPSLN) {
	        Chi = this.X0;
	      }
	      else {
	        Chi = Math.asin(Math.cos(ce) * this.sinX0 + p.y * Math.sin(ce) * this.cosX0 / rh);
	        lon = adjust_lon(this.long0 + Math.atan2(p.x * Math.sin(ce), rh * this.cosX0 * Math.cos(ce) - p.y * this.sinX0 * Math.sin(ce)));
	      }
	      lat = -1 * phi2z(this.e, Math.tan(0.5 * (HALF_PI + Chi)));
	    }
	  }
	  p.x = lon;
	  p.y = lat;

	  //trace(p.toString());
	  return p;

	}

	var names$8 = ["stere", "Stereographic_South_Pole", "Polar Stereographic (variant B)"];
	var stere = {
	  init: init$7,
	  forward: forward$6,
	  inverse: inverse$6,
	  names: names$8,
	  ssfn_: ssfn_
	};

	/*
	  references:
	    Formules et constantes pour le Calcul pour la
	    projection cylindrique conforme à axe oblique et pour la transformation entre
	    des systèmes de référence.
	    http://www.swisstopo.admin.ch/internet/swisstopo/fr/home/topics/survey/sys/refsys/switzerland.parsysrelated1.31216.downloadList.77004.DownloadFile.tmp/swissprojectionfr.pdf
	  */

	function init$8() {
	  var phy0 = this.lat0;
	  this.lambda0 = this.long0;
	  var sinPhy0 = Math.sin(phy0);
	  var semiMajorAxis = this.a;
	  var invF = this.rf;
	  var flattening = 1 / invF;
	  var e2 = 2 * flattening - Math.pow(flattening, 2);
	  var e = this.e = Math.sqrt(e2);
	  this.R = this.k0 * semiMajorAxis * Math.sqrt(1 - e2) / (1 - e2 * Math.pow(sinPhy0, 2));
	  this.alpha = Math.sqrt(1 + e2 / (1 - e2) * Math.pow(Math.cos(phy0), 4));
	  this.b0 = Math.asin(sinPhy0 / this.alpha);
	  var k1 = Math.log(Math.tan(Math.PI / 4 + this.b0 / 2));
	  var k2 = Math.log(Math.tan(Math.PI / 4 + phy0 / 2));
	  var k3 = Math.log((1 + e * sinPhy0) / (1 - e * sinPhy0));
	  this.K = k1 - this.alpha * k2 + this.alpha * e / 2 * k3;
	}

	function forward$7(p) {
	  var Sa1 = Math.log(Math.tan(Math.PI / 4 - p.y / 2));
	  var Sa2 = this.e / 2 * Math.log((1 + this.e * Math.sin(p.y)) / (1 - this.e * Math.sin(p.y)));
	  var S = -this.alpha * (Sa1 + Sa2) + this.K;

	  // spheric latitude
	  var b = 2 * (Math.atan(Math.exp(S)) - Math.PI / 4);

	  // spheric longitude
	  var I = this.alpha * (p.x - this.lambda0);

	  // psoeudo equatorial rotation
	  var rotI = Math.atan(Math.sin(I) / (Math.sin(this.b0) * Math.tan(b) + Math.cos(this.b0) * Math.cos(I)));

	  var rotB = Math.asin(Math.cos(this.b0) * Math.sin(b) - Math.sin(this.b0) * Math.cos(b) * Math.cos(I));

	  p.y = this.R / 2 * Math.log((1 + Math.sin(rotB)) / (1 - Math.sin(rotB))) + this.y0;
	  p.x = this.R * rotI + this.x0;
	  return p;
	}

	function inverse$7(p) {
	  var Y = p.x - this.x0;
	  var X = p.y - this.y0;

	  var rotI = Y / this.R;
	  var rotB = 2 * (Math.atan(Math.exp(X / this.R)) - Math.PI / 4);

	  var b = Math.asin(Math.cos(this.b0) * Math.sin(rotB) + Math.sin(this.b0) * Math.cos(rotB) * Math.cos(rotI));
	  var I = Math.atan(Math.sin(rotI) / (Math.cos(this.b0) * Math.cos(rotI) - Math.sin(this.b0) * Math.tan(rotB)));

	  var lambda = this.lambda0 + I / this.alpha;

	  var S = 0;
	  var phy = b;
	  var prevPhy = -1000;
	  var iteration = 0;
	  while (Math.abs(phy - prevPhy) > 0.0000001) {
	    if (++iteration > 20) {
	      //...reportError("omercFwdInfinity");
	      return;
	    }
	    //S = Math.log(Math.tan(Math.PI / 4 + phy / 2));
	    S = 1 / this.alpha * (Math.log(Math.tan(Math.PI / 4 + b / 2)) - this.K) + this.e * Math.log(Math.tan(Math.PI / 4 + Math.asin(this.e * Math.sin(phy)) / 2));
	    prevPhy = phy;
	    phy = 2 * Math.atan(Math.exp(S)) - Math.PI / 2;
	  }

	  p.x = lambda;
	  p.y = phy;
	  return p;
	}

	var names$9 = ["somerc"];
	var somerc = {
	  init: init$8,
	  forward: forward$7,
	  inverse: inverse$7,
	  names: names$9
	};

	/* Initialize the Oblique Mercator  projection
	    ------------------------------------------*/
	function init$9() {
	  this.no_off = this.no_off || false;
	  this.no_rot = this.no_rot || false;

	  if (isNaN(this.k0)) {
	    this.k0 = 1;
	  }
	  var sinlat = Math.sin(this.lat0);
	  var coslat = Math.cos(this.lat0);
	  var con = this.e * sinlat;

	  this.bl = Math.sqrt(1 + this.es / (1 - this.es) * Math.pow(coslat, 4));
	  this.al = this.a * this.bl * this.k0 * Math.sqrt(1 - this.es) / (1 - con * con);
	  var t0 = tsfnz(this.e, this.lat0, sinlat);
	  var dl = this.bl / coslat * Math.sqrt((1 - this.es) / (1 - con * con));
	  if (dl * dl < 1) {
	    dl = 1;
	  }
	  var fl;
	  var gl;
	  if (!isNaN(this.longc)) {
	    //Central point and azimuth method

	    if (this.lat0 >= 0) {
	      fl = dl + Math.sqrt(dl * dl - 1);
	    }
	    else {
	      fl = dl - Math.sqrt(dl * dl - 1);
	    }
	    this.el = fl * Math.pow(t0, this.bl);
	    gl = 0.5 * (fl - 1 / fl);
	    this.gamma0 = Math.asin(Math.sin(this.alpha) / dl);
	    this.long0 = this.longc - Math.asin(gl * Math.tan(this.gamma0)) / this.bl;

	  }
	  else {
	    //2 points method
	    var t1 = tsfnz(this.e, this.lat1, Math.sin(this.lat1));
	    var t2 = tsfnz(this.e, this.lat2, Math.sin(this.lat2));
	    if (this.lat0 >= 0) {
	      this.el = (dl + Math.sqrt(dl * dl - 1)) * Math.pow(t0, this.bl);
	    }
	    else {
	      this.el = (dl - Math.sqrt(dl * dl - 1)) * Math.pow(t0, this.bl);
	    }
	    var hl = Math.pow(t1, this.bl);
	    var ll = Math.pow(t2, this.bl);
	    fl = this.el / hl;
	    gl = 0.5 * (fl - 1 / fl);
	    var jl = (this.el * this.el - ll * hl) / (this.el * this.el + ll * hl);
	    var pl = (ll - hl) / (ll + hl);
	    var dlon12 = adjust_lon(this.long1 - this.long2);
	    this.long0 = 0.5 * (this.long1 + this.long2) - Math.atan(jl * Math.tan(0.5 * this.bl * (dlon12)) / pl) / this.bl;
	    this.long0 = adjust_lon(this.long0);
	    var dlon10 = adjust_lon(this.long1 - this.long0);
	    this.gamma0 = Math.atan(Math.sin(this.bl * (dlon10)) / gl);
	    this.alpha = Math.asin(dl * Math.sin(this.gamma0));
	  }

	  if (this.no_off) {
	    this.uc = 0;
	  }
	  else {
	    if (this.lat0 >= 0) {
	      this.uc = this.al / this.bl * Math.atan2(Math.sqrt(dl * dl - 1), Math.cos(this.alpha));
	    }
	    else {
	      this.uc = -1 * this.al / this.bl * Math.atan2(Math.sqrt(dl * dl - 1), Math.cos(this.alpha));
	    }
	  }

	}

	/* Oblique Mercator forward equations--mapping lat,long to x,y
	    ----------------------------------------------------------*/
	function forward$8(p) {
	  var lon = p.x;
	  var lat = p.y;
	  var dlon = adjust_lon(lon - this.long0);
	  var us, vs;
	  var con;
	  if (Math.abs(Math.abs(lat) - HALF_PI) <= EPSLN) {
	    if (lat > 0) {
	      con = -1;
	    }
	    else {
	      con = 1;
	    }
	    vs = this.al / this.bl * Math.log(Math.tan(FORTPI + con * this.gamma0 * 0.5));
	    us = -1 * con * HALF_PI * this.al / this.bl;
	  }
	  else {
	    var t = tsfnz(this.e, lat, Math.sin(lat));
	    var ql = this.el / Math.pow(t, this.bl);
	    var sl = 0.5 * (ql - 1 / ql);
	    var tl = 0.5 * (ql + 1 / ql);
	    var vl = Math.sin(this.bl * (dlon));
	    var ul = (sl * Math.sin(this.gamma0) - vl * Math.cos(this.gamma0)) / tl;
	    if (Math.abs(Math.abs(ul) - 1) <= EPSLN) {
	      vs = Number.POSITIVE_INFINITY;
	    }
	    else {
	      vs = 0.5 * this.al * Math.log((1 - ul) / (1 + ul)) / this.bl;
	    }
	    if (Math.abs(Math.cos(this.bl * (dlon))) <= EPSLN) {
	      us = this.al * this.bl * (dlon);
	    }
	    else {
	      us = this.al * Math.atan2(sl * Math.cos(this.gamma0) + vl * Math.sin(this.gamma0), Math.cos(this.bl * dlon)) / this.bl;
	    }
	  }

	  if (this.no_rot) {
	    p.x = this.x0 + us;
	    p.y = this.y0 + vs;
	  }
	  else {

	    us -= this.uc;
	    p.x = this.x0 + vs * Math.cos(this.alpha) + us * Math.sin(this.alpha);
	    p.y = this.y0 + us * Math.cos(this.alpha) - vs * Math.sin(this.alpha);
	  }
	  return p;
	}

	function inverse$8(p) {
	  var us, vs;
	  if (this.no_rot) {
	    vs = p.y - this.y0;
	    us = p.x - this.x0;
	  }
	  else {
	    vs = (p.x - this.x0) * Math.cos(this.alpha) - (p.y - this.y0) * Math.sin(this.alpha);
	    us = (p.y - this.y0) * Math.cos(this.alpha) + (p.x - this.x0) * Math.sin(this.alpha);
	    us += this.uc;
	  }
	  var qp = Math.exp(-1 * this.bl * vs / this.al);
	  var sp = 0.5 * (qp - 1 / qp);
	  var tp = 0.5 * (qp + 1 / qp);
	  var vp = Math.sin(this.bl * us / this.al);
	  var up = (vp * Math.cos(this.gamma0) + sp * Math.sin(this.gamma0)) / tp;
	  var ts = Math.pow(this.el / Math.sqrt((1 + up) / (1 - up)), 1 / this.bl);
	  if (Math.abs(up - 1) < EPSLN) {
	    p.x = this.long0;
	    p.y = HALF_PI;
	  }
	  else if (Math.abs(up + 1) < EPSLN) {
	    p.x = this.long0;
	    p.y = -1 * HALF_PI;
	  }
	  else {
	    p.y = phi2z(this.e, ts);
	    p.x = adjust_lon(this.long0 - Math.atan2(sp * Math.cos(this.gamma0) - vp * Math.sin(this.gamma0), Math.cos(this.bl * us / this.al)) / this.bl);
	  }
	  return p;
	}

	var names$10 = ["Hotine_Oblique_Mercator", "Hotine Oblique Mercator", "Hotine_Oblique_Mercator_Azimuth_Natural_Origin", "Hotine_Oblique_Mercator_Azimuth_Center", "omerc"];
	var omerc = {
	  init: init$9,
	  forward: forward$8,
	  inverse: inverse$8,
	  names: names$10
	};

	function init$10() {

	  // array of:  r_maj,r_min,lat1,lat2,c_lon,c_lat,false_east,false_north
	  //double c_lat;                   /* center latitude                      */
	  //double c_lon;                   /* center longitude                     */
	  //double lat1;                    /* first standard parallel              */
	  //double lat2;                    /* second standard parallel             */
	  //double r_maj;                   /* major axis                           */
	  //double r_min;                   /* minor axis                           */
	  //double false_east;              /* x offset in meters                   */
	  //double false_north;             /* y offset in meters                   */

	  if (!this.lat2) {
	    this.lat2 = this.lat1;
	  } //if lat2 is not defined
	  if (!this.k0) {
	    this.k0 = 1;
	  }
	  this.x0 = this.x0 || 0;
	  this.y0 = this.y0 || 0;
	  // Standard Parallels cannot be equal and on opposite sides of the equator
	  if (Math.abs(this.lat1 + this.lat2) < EPSLN) {
	    return;
	  }

	  var temp = this.b / this.a;
	  this.e = Math.sqrt(1 - temp * temp);

	  var sin1 = Math.sin(this.lat1);
	  var cos1 = Math.cos(this.lat1);
	  var ms1 = msfnz(this.e, sin1, cos1);
	  var ts1 = tsfnz(this.e, this.lat1, sin1);

	  var sin2 = Math.sin(this.lat2);
	  var cos2 = Math.cos(this.lat2);
	  var ms2 = msfnz(this.e, sin2, cos2);
	  var ts2 = tsfnz(this.e, this.lat2, sin2);

	  var ts0 = tsfnz(this.e, this.lat0, Math.sin(this.lat0));

	  if (Math.abs(this.lat1 - this.lat2) > EPSLN) {
	    this.ns = Math.log(ms1 / ms2) / Math.log(ts1 / ts2);
	  }
	  else {
	    this.ns = sin1;
	  }
	  if (isNaN(this.ns)) {
	    this.ns = sin1;
	  }
	  this.f0 = ms1 / (this.ns * Math.pow(ts1, this.ns));
	  this.rh = this.a * this.f0 * Math.pow(ts0, this.ns);
	  if (!this.title) {
	    this.title = "Lambert Conformal Conic";
	  }
	}

	// Lambert Conformal conic forward equations--mapping lat,long to x,y
	// -----------------------------------------------------------------
	function forward$9(p) {

	  var lon = p.x;
	  var lat = p.y;

	  // singular cases :
	  if (Math.abs(2 * Math.abs(lat) - Math.PI) <= EPSLN) {
	    lat = sign(lat) * (HALF_PI - 2 * EPSLN);
	  }

	  var con = Math.abs(Math.abs(lat) - HALF_PI);
	  var ts, rh1;
	  if (con > EPSLN) {
	    ts = tsfnz(this.e, lat, Math.sin(lat));
	    rh1 = this.a * this.f0 * Math.pow(ts, this.ns);
	  }
	  else {
	    con = lat * this.ns;
	    if (con <= 0) {
	      return null;
	    }
	    rh1 = 0;
	  }
	  var theta = this.ns * adjust_lon(lon - this.long0);
	  p.x = this.k0 * (rh1 * Math.sin(theta)) + this.x0;
	  p.y = this.k0 * (this.rh - rh1 * Math.cos(theta)) + this.y0;

	  return p;
	}

	// Lambert Conformal Conic inverse equations--mapping x,y to lat/long
	// -----------------------------------------------------------------
	function inverse$9(p) {

	  var rh1, con, ts;
	  var lat, lon;
	  var x = (p.x - this.x0) / this.k0;
	  var y = (this.rh - (p.y - this.y0) / this.k0);
	  if (this.ns > 0) {
	    rh1 = Math.sqrt(x * x + y * y);
	    con = 1;
	  }
	  else {
	    rh1 = -Math.sqrt(x * x + y * y);
	    con = -1;
	  }
	  var theta = 0;
	  if (rh1 !== 0) {
	    theta = Math.atan2((con * x), (con * y));
	  }
	  if ((rh1 !== 0) || (this.ns > 0)) {
	    con = 1 / this.ns;
	    ts = Math.pow((rh1 / (this.a * this.f0)), con);
	    lat = phi2z(this.e, ts);
	    if (lat === -9999) {
	      return null;
	    }
	  }
	  else {
	    lat = -HALF_PI;
	  }
	  lon = adjust_lon(theta / this.ns + this.long0);

	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$11 = ["Lambert Tangential Conformal Conic Projection", "Lambert_Conformal_Conic", "Lambert_Conformal_Conic_2SP", "lcc"];
	var lcc = {
	  init: init$10,
	  forward: forward$9,
	  inverse: inverse$9,
	  names: names$11
	};

	function init$11() {
	  this.a = 6377397.155;
	  this.es = 0.006674372230614;
	  this.e = Math.sqrt(this.es);
	  if (!this.lat0) {
	    this.lat0 = 0.863937979737193;
	  }
	  if (!this.long0) {
	    this.long0 = 0.7417649320975901 - 0.308341501185665;
	  }
	  /* if scale not set default to 0.9999 */
	  if (!this.k0) {
	    this.k0 = 0.9999;
	  }
	  this.s45 = 0.785398163397448; /* 45 */
	  this.s90 = 2 * this.s45;
	  this.fi0 = this.lat0;
	  this.e2 = this.es;
	  this.e = Math.sqrt(this.e2);
	  this.alfa = Math.sqrt(1 + (this.e2 * Math.pow(Math.cos(this.fi0), 4)) / (1 - this.e2));
	  this.uq = 1.04216856380474;
	  this.u0 = Math.asin(Math.sin(this.fi0) / this.alfa);
	  this.g = Math.pow((1 + this.e * Math.sin(this.fi0)) / (1 - this.e * Math.sin(this.fi0)), this.alfa * this.e / 2);
	  this.k = Math.tan(this.u0 / 2 + this.s45) / Math.pow(Math.tan(this.fi0 / 2 + this.s45), this.alfa) * this.g;
	  this.k1 = this.k0;
	  this.n0 = this.a * Math.sqrt(1 - this.e2) / (1 - this.e2 * Math.pow(Math.sin(this.fi0), 2));
	  this.s0 = 1.37008346281555;
	  this.n = Math.sin(this.s0);
	  this.ro0 = this.k1 * this.n0 / Math.tan(this.s0);
	  this.ad = this.s90 - this.uq;
	}

	/* ellipsoid */
	/* calculate xy from lat/lon */
	/* Constants, identical to inverse transform function */
	function forward$10(p) {
	  var gfi, u, deltav, s, d, eps, ro;
	  var lon = p.x;
	  var lat = p.y;
	  var delta_lon = adjust_lon(lon - this.long0);
	  /* Transformation */
	  gfi = Math.pow(((1 + this.e * Math.sin(lat)) / (1 - this.e * Math.sin(lat))), (this.alfa * this.e / 2));
	  u = 2 * (Math.atan(this.k * Math.pow(Math.tan(lat / 2 + this.s45), this.alfa) / gfi) - this.s45);
	  deltav = -delta_lon * this.alfa;
	  s = Math.asin(Math.cos(this.ad) * Math.sin(u) + Math.sin(this.ad) * Math.cos(u) * Math.cos(deltav));
	  d = Math.asin(Math.cos(u) * Math.sin(deltav) / Math.cos(s));
	  eps = this.n * d;
	  ro = this.ro0 * Math.pow(Math.tan(this.s0 / 2 + this.s45), this.n) / Math.pow(Math.tan(s / 2 + this.s45), this.n);
	  p.y = ro * Math.cos(eps) / 1;
	  p.x = ro * Math.sin(eps) / 1;

	  if (!this.czech) {
	    p.y *= -1;
	    p.x *= -1;
	  }
	  return (p);
	}

	/* calculate lat/lon from xy */
	function inverse$10(p) {
	  var u, deltav, s, d, eps, ro, fi1;
	  var ok;

	  /* Transformation */
	  /* revert y, x*/
	  var tmp = p.x;
	  p.x = p.y;
	  p.y = tmp;
	  if (!this.czech) {
	    p.y *= -1;
	    p.x *= -1;
	  }
	  ro = Math.sqrt(p.x * p.x + p.y * p.y);
	  eps = Math.atan2(p.y, p.x);
	  d = eps / Math.sin(this.s0);
	  s = 2 * (Math.atan(Math.pow(this.ro0 / ro, 1 / this.n) * Math.tan(this.s0 / 2 + this.s45)) - this.s45);
	  u = Math.asin(Math.cos(this.ad) * Math.sin(s) - Math.sin(this.ad) * Math.cos(s) * Math.cos(d));
	  deltav = Math.asin(Math.cos(s) * Math.sin(d) / Math.cos(u));
	  p.x = this.long0 - deltav / this.alfa;
	  fi1 = u;
	  ok = 0;
	  var iter = 0;
	  do {
	    p.y = 2 * (Math.atan(Math.pow(this.k, - 1 / this.alfa) * Math.pow(Math.tan(u / 2 + this.s45), 1 / this.alfa) * Math.pow((1 + this.e * Math.sin(fi1)) / (1 - this.e * Math.sin(fi1)), this.e / 2)) - this.s45);
	    if (Math.abs(fi1 - p.y) < 0.0000000001) {
	      ok = 1;
	    }
	    fi1 = p.y;
	    iter += 1;
	  } while (ok === 0 && iter < 15);
	  if (iter >= 15) {
	    return null;
	  }

	  return (p);
	}

	var names$12 = ["Krovak", "krovak"];
	var krovak = {
	  init: init$11,
	  forward: forward$10,
	  inverse: inverse$10,
	  names: names$12
	};

	var mlfn = function(e0, e1, e2, e3, phi) {
	  return (e0 * phi - e1 * Math.sin(2 * phi) + e2 * Math.sin(4 * phi) - e3 * Math.sin(6 * phi));
	};

	var e0fn = function(x) {
	  return (1 - 0.25 * x * (1 + x / 16 * (3 + 1.25 * x)));
	};

	var e1fn = function(x) {
	  return (0.375 * x * (1 + 0.25 * x * (1 + 0.46875 * x)));
	};

	var e2fn = function(x) {
	  return (0.05859375 * x * x * (1 + 0.75 * x));
	};

	var e3fn = function(x) {
	  return (x * x * x * (35 / 3072));
	};

	var gN = function(a, e, sinphi) {
	  var temp = e * sinphi;
	  return a / Math.sqrt(1 - temp * temp);
	};

	var adjust_lat = function(x) {
	  return (Math.abs(x) < HALF_PI) ? x : (x - (sign(x) * Math.PI));
	};

	var imlfn = function(ml, e0, e1, e2, e3) {
	  var phi;
	  var dphi;

	  phi = ml / e0;
	  for (var i = 0; i < 15; i++) {
	    dphi = (ml - (e0 * phi - e1 * Math.sin(2 * phi) + e2 * Math.sin(4 * phi) - e3 * Math.sin(6 * phi))) / (e0 - 2 * e1 * Math.cos(2 * phi) + 4 * e2 * Math.cos(4 * phi) - 6 * e3 * Math.cos(6 * phi));
	    phi += dphi;
	    if (Math.abs(dphi) <= 0.0000000001) {
	      return phi;
	    }
	  }

	  //..reportError("IMLFN-CONV:Latitude failed to converge after 15 iterations");
	  return NaN;
	};

	function init$12() {
	  if (!this.sphere) {
	    this.e0 = e0fn(this.es);
	    this.e1 = e1fn(this.es);
	    this.e2 = e2fn(this.es);
	    this.e3 = e3fn(this.es);
	    this.ml0 = this.a * mlfn(this.e0, this.e1, this.e2, this.e3, this.lat0);
	  }
	}

	/* Cassini forward equations--mapping lat,long to x,y
	  -----------------------------------------------------------------------*/
	function forward$11(p) {

	  /* Forward equations
	      -----------------*/
	  var x, y;
	  var lam = p.x;
	  var phi = p.y;
	  lam = adjust_lon(lam - this.long0);

	  if (this.sphere) {
	    x = this.a * Math.asin(Math.cos(phi) * Math.sin(lam));
	    y = this.a * (Math.atan2(Math.tan(phi), Math.cos(lam)) - this.lat0);
	  }
	  else {
	    //ellipsoid
	    var sinphi = Math.sin(phi);
	    var cosphi = Math.cos(phi);
	    var nl = gN(this.a, this.e, sinphi);
	    var tl = Math.tan(phi) * Math.tan(phi);
	    var al = lam * Math.cos(phi);
	    var asq = al * al;
	    var cl = this.es * cosphi * cosphi / (1 - this.es);
	    var ml = this.a * mlfn(this.e0, this.e1, this.e2, this.e3, phi);

	    x = nl * al * (1 - asq * tl * (1 / 6 - (8 - tl + 8 * cl) * asq / 120));
	    y = ml - this.ml0 + nl * sinphi / cosphi * asq * (0.5 + (5 - tl + 6 * cl) * asq / 24);


	  }

	  p.x = x + this.x0;
	  p.y = y + this.y0;
	  return p;
	}

	/* Inverse equations
	  -----------------*/
	function inverse$11(p) {
	  p.x -= this.x0;
	  p.y -= this.y0;
	  var x = p.x / this.a;
	  var y = p.y / this.a;
	  var phi, lam;

	  if (this.sphere) {
	    var dd = y + this.lat0;
	    phi = Math.asin(Math.sin(dd) * Math.cos(x));
	    lam = Math.atan2(Math.tan(x), Math.cos(dd));
	  }
	  else {
	    /* ellipsoid */
	    var ml1 = this.ml0 / this.a + y;
	    var phi1 = imlfn(ml1, this.e0, this.e1, this.e2, this.e3);
	    if (Math.abs(Math.abs(phi1) - HALF_PI) <= EPSLN) {
	      p.x = this.long0;
	      p.y = HALF_PI;
	      if (y < 0) {
	        p.y *= -1;
	      }
	      return p;
	    }
	    var nl1 = gN(this.a, this.e, Math.sin(phi1));

	    var rl1 = nl1 * nl1 * nl1 / this.a / this.a * (1 - this.es);
	    var tl1 = Math.pow(Math.tan(phi1), 2);
	    var dl = x * this.a / nl1;
	    var dsq = dl * dl;
	    phi = phi1 - nl1 * Math.tan(phi1) / rl1 * dl * dl * (0.5 - (1 + 3 * tl1) * dl * dl / 24);
	    lam = dl * (1 - dsq * (tl1 / 3 + (1 + 3 * tl1) * tl1 * dsq / 15)) / Math.cos(phi1);

	  }

	  p.x = adjust_lon(lam + this.long0);
	  p.y = adjust_lat(phi);
	  return p;

	}

	var names$13 = ["Cassini", "Cassini_Soldner", "cass"];
	var cass = {
	  init: init$12,
	  forward: forward$11,
	  inverse: inverse$11,
	  names: names$13
	};

	var qsfnz = function(eccent, sinphi) {
	  var con;
	  if (eccent > 1.0e-7) {
	    con = eccent * sinphi;
	    return ((1 - eccent * eccent) * (sinphi / (1 - con * con) - (0.5 / eccent) * Math.log((1 - con) / (1 + con))));
	  }
	  else {
	    return (2 * sinphi);
	  }
	};

	/*
	  reference
	    "New Equal-Area Map Projections for Noncircular Regions", John P. Snyder,
	    The American Cartographer, Vol 15, No. 4, October 1988, pp. 341-355.
	  */

	var S_POLE = 1;

	var N_POLE = 2;
	var EQUIT = 3;
	var OBLIQ = 4;

	/* Initialize the Lambert Azimuthal Equal Area projection
	  ------------------------------------------------------*/
	function init$13() {
	  var t = Math.abs(this.lat0);
	  if (Math.abs(t - HALF_PI) < EPSLN) {
	    this.mode = this.lat0 < 0 ? this.S_POLE : this.N_POLE;
	  }
	  else if (Math.abs(t) < EPSLN) {
	    this.mode = this.EQUIT;
	  }
	  else {
	    this.mode = this.OBLIQ;
	  }
	  if (this.es > 0) {
	    var sinphi;

	    this.qp = qsfnz(this.e, 1);
	    this.mmf = 0.5 / (1 - this.es);
	    this.apa = authset(this.es);
	    switch (this.mode) {
	    case this.N_POLE:
	      this.dd = 1;
	      break;
	    case this.S_POLE:
	      this.dd = 1;
	      break;
	    case this.EQUIT:
	      this.rq = Math.sqrt(0.5 * this.qp);
	      this.dd = 1 / this.rq;
	      this.xmf = 1;
	      this.ymf = 0.5 * this.qp;
	      break;
	    case this.OBLIQ:
	      this.rq = Math.sqrt(0.5 * this.qp);
	      sinphi = Math.sin(this.lat0);
	      this.sinb1 = qsfnz(this.e, sinphi) / this.qp;
	      this.cosb1 = Math.sqrt(1 - this.sinb1 * this.sinb1);
	      this.dd = Math.cos(this.lat0) / (Math.sqrt(1 - this.es * sinphi * sinphi) * this.rq * this.cosb1);
	      this.ymf = (this.xmf = this.rq) / this.dd;
	      this.xmf *= this.dd;
	      break;
	    }
	  }
	  else {
	    if (this.mode === this.OBLIQ) {
	      this.sinph0 = Math.sin(this.lat0);
	      this.cosph0 = Math.cos(this.lat0);
	    }
	  }
	}

	/* Lambert Azimuthal Equal Area forward equations--mapping lat,long to x,y
	  -----------------------------------------------------------------------*/
	function forward$12(p) {

	  /* Forward equations
	      -----------------*/
	  var x, y, coslam, sinlam, sinphi, q, sinb, cosb, b, cosphi;
	  var lam = p.x;
	  var phi = p.y;

	  lam = adjust_lon(lam - this.long0);
	  if (this.sphere) {
	    sinphi = Math.sin(phi);
	    cosphi = Math.cos(phi);
	    coslam = Math.cos(lam);
	    if (this.mode === this.OBLIQ || this.mode === this.EQUIT) {
	      y = (this.mode === this.EQUIT) ? 1 + cosphi * coslam : 1 + this.sinph0 * sinphi + this.cosph0 * cosphi * coslam;
	      if (y <= EPSLN) {
	        return null;
	      }
	      y = Math.sqrt(2 / y);
	      x = y * cosphi * Math.sin(lam);
	      y *= (this.mode === this.EQUIT) ? sinphi : this.cosph0 * sinphi - this.sinph0 * cosphi * coslam;
	    }
	    else if (this.mode === this.N_POLE || this.mode === this.S_POLE) {
	      if (this.mode === this.N_POLE) {
	        coslam = -coslam;
	      }
	      if (Math.abs(phi + this.phi0) < EPSLN) {
	        return null;
	      }
	      y = FORTPI - phi * 0.5;
	      y = 2 * ((this.mode === this.S_POLE) ? Math.cos(y) : Math.sin(y));
	      x = y * Math.sin(lam);
	      y *= coslam;
	    }
	  }
	  else {
	    sinb = 0;
	    cosb = 0;
	    b = 0;
	    coslam = Math.cos(lam);
	    sinlam = Math.sin(lam);
	    sinphi = Math.sin(phi);
	    q = qsfnz(this.e, sinphi);
	    if (this.mode === this.OBLIQ || this.mode === this.EQUIT) {
	      sinb = q / this.qp;
	      cosb = Math.sqrt(1 - sinb * sinb);
	    }
	    switch (this.mode) {
	    case this.OBLIQ:
	      b = 1 + this.sinb1 * sinb + this.cosb1 * cosb * coslam;
	      break;
	    case this.EQUIT:
	      b = 1 + cosb * coslam;
	      break;
	    case this.N_POLE:
	      b = HALF_PI + phi;
	      q = this.qp - q;
	      break;
	    case this.S_POLE:
	      b = phi - HALF_PI;
	      q = this.qp + q;
	      break;
	    }
	    if (Math.abs(b) < EPSLN) {
	      return null;
	    }
	    switch (this.mode) {
	    case this.OBLIQ:
	    case this.EQUIT:
	      b = Math.sqrt(2 / b);
	      if (this.mode === this.OBLIQ) {
	        y = this.ymf * b * (this.cosb1 * sinb - this.sinb1 * cosb * coslam);
	      }
	      else {
	        y = (b = Math.sqrt(2 / (1 + cosb * coslam))) * sinb * this.ymf;
	      }
	      x = this.xmf * b * cosb * sinlam;
	      break;
	    case this.N_POLE:
	    case this.S_POLE:
	      if (q >= 0) {
	        x = (b = Math.sqrt(q)) * sinlam;
	        y = coslam * ((this.mode === this.S_POLE) ? b : -b);
	      }
	      else {
	        x = y = 0;
	      }
	      break;
	    }
	  }

	  p.x = this.a * x + this.x0;
	  p.y = this.a * y + this.y0;
	  return p;
	}

	/* Inverse equations
	  -----------------*/
	function inverse$12(p) {
	  p.x -= this.x0;
	  p.y -= this.y0;
	  var x = p.x / this.a;
	  var y = p.y / this.a;
	  var lam, phi, cCe, sCe, q, rho, ab;
	  if (this.sphere) {
	    var cosz = 0,
	      rh, sinz = 0;

	    rh = Math.sqrt(x * x + y * y);
	    phi = rh * 0.5;
	    if (phi > 1) {
	      return null;
	    }
	    phi = 2 * Math.asin(phi);
	    if (this.mode === this.OBLIQ || this.mode === this.EQUIT) {
	      sinz = Math.sin(phi);
	      cosz = Math.cos(phi);
	    }
	    switch (this.mode) {
	    case this.EQUIT:
	      phi = (Math.abs(rh) <= EPSLN) ? 0 : Math.asin(y * sinz / rh);
	      x *= sinz;
	      y = cosz * rh;
	      break;
	    case this.OBLIQ:
	      phi = (Math.abs(rh) <= EPSLN) ? this.phi0 : Math.asin(cosz * this.sinph0 + y * sinz * this.cosph0 / rh);
	      x *= sinz * this.cosph0;
	      y = (cosz - Math.sin(phi) * this.sinph0) * rh;
	      break;
	    case this.N_POLE:
	      y = -y;
	      phi = HALF_PI - phi;
	      break;
	    case this.S_POLE:
	      phi -= HALF_PI;
	      break;
	    }
	    lam = (y === 0 && (this.mode === this.EQUIT || this.mode === this.OBLIQ)) ? 0 : Math.atan2(x, y);
	  }
	  else {
	    ab = 0;
	    if (this.mode === this.OBLIQ || this.mode === this.EQUIT) {
	      x /= this.dd;
	      y *= this.dd;
	      rho = Math.sqrt(x * x + y * y);
	      if (rho < EPSLN) {
	        p.x = 0;
	        p.y = this.phi0;
	        return p;
	      }
	      sCe = 2 * Math.asin(0.5 * rho / this.rq);
	      cCe = Math.cos(sCe);
	      x *= (sCe = Math.sin(sCe));
	      if (this.mode === this.OBLIQ) {
	        ab = cCe * this.sinb1 + y * sCe * this.cosb1 / rho;
	        q = this.qp * ab;
	        y = rho * this.cosb1 * cCe - y * this.sinb1 * sCe;
	      }
	      else {
	        ab = y * sCe / rho;
	        q = this.qp * ab;
	        y = rho * cCe;
	      }
	    }
	    else if (this.mode === this.N_POLE || this.mode === this.S_POLE) {
	      if (this.mode === this.N_POLE) {
	        y = -y;
	      }
	      q = (x * x + y * y);
	      if (!q) {
	        p.x = 0;
	        p.y = this.phi0;
	        return p;
	      }
	      ab = 1 - q / this.qp;
	      if (this.mode === this.S_POLE) {
	        ab = -ab;
	      }
	    }
	    lam = Math.atan2(x, y);
	    phi = authlat(Math.asin(ab), this.apa);
	  }

	  p.x = adjust_lon(this.long0 + lam);
	  p.y = phi;
	  return p;
	}

	/* determine latitude from authalic latitude */
	var P00 = 0.33333333333333333333;

	var P01 = 0.17222222222222222222;
	var P02 = 0.10257936507936507936;
	var P10 = 0.06388888888888888888;
	var P11 = 0.06640211640211640211;
	var P20 = 0.01641501294219154443;

	function authset(es) {
	  var t;
	  var APA = [];
	  APA[0] = es * P00;
	  t = es * es;
	  APA[0] += t * P01;
	  APA[1] = t * P10;
	  t *= es;
	  APA[0] += t * P02;
	  APA[1] += t * P11;
	  APA[2] = t * P20;
	  return APA;
	}

	function authlat(beta, APA) {
	  var t = beta + beta;
	  return (beta + APA[0] * Math.sin(t) + APA[1] * Math.sin(t + t) + APA[2] * Math.sin(t + t + t));
	}

	var names$14 = ["Lambert Azimuthal Equal Area", "Lambert_Azimuthal_Equal_Area", "laea"];
	var laea = {
	  init: init$13,
	  forward: forward$12,
	  inverse: inverse$12,
	  names: names$14,
	  S_POLE: S_POLE,
	  N_POLE: N_POLE,
	  EQUIT: EQUIT,
	  OBLIQ: OBLIQ
	};

	var asinz = function(x) {
	  if (Math.abs(x) > 1) {
	    x = (x > 1) ? 1 : -1;
	  }
	  return Math.asin(x);
	};

	function init$14() {

	  if (Math.abs(this.lat1 + this.lat2) < EPSLN) {
	    return;
	  }
	  this.temp = this.b / this.a;
	  this.es = 1 - Math.pow(this.temp, 2);
	  this.e3 = Math.sqrt(this.es);

	  this.sin_po = Math.sin(this.lat1);
	  this.cos_po = Math.cos(this.lat1);
	  this.t1 = this.sin_po;
	  this.con = this.sin_po;
	  this.ms1 = msfnz(this.e3, this.sin_po, this.cos_po);
	  this.qs1 = qsfnz(this.e3, this.sin_po, this.cos_po);

	  this.sin_po = Math.sin(this.lat2);
	  this.cos_po = Math.cos(this.lat2);
	  this.t2 = this.sin_po;
	  this.ms2 = msfnz(this.e3, this.sin_po, this.cos_po);
	  this.qs2 = qsfnz(this.e3, this.sin_po, this.cos_po);

	  this.sin_po = Math.sin(this.lat0);
	  this.cos_po = Math.cos(this.lat0);
	  this.t3 = this.sin_po;
	  this.qs0 = qsfnz(this.e3, this.sin_po, this.cos_po);

	  if (Math.abs(this.lat1 - this.lat2) > EPSLN) {
	    this.ns0 = (this.ms1 * this.ms1 - this.ms2 * this.ms2) / (this.qs2 - this.qs1);
	  }
	  else {
	    this.ns0 = this.con;
	  }
	  this.c = this.ms1 * this.ms1 + this.ns0 * this.qs1;
	  this.rh = this.a * Math.sqrt(this.c - this.ns0 * this.qs0) / this.ns0;
	}

	/* Albers Conical Equal Area forward equations--mapping lat,long to x,y
	  -------------------------------------------------------------------*/
	function forward$13(p) {

	  var lon = p.x;
	  var lat = p.y;

	  this.sin_phi = Math.sin(lat);
	  this.cos_phi = Math.cos(lat);

	  var qs = qsfnz(this.e3, this.sin_phi, this.cos_phi);
	  var rh1 = this.a * Math.sqrt(this.c - this.ns0 * qs) / this.ns0;
	  var theta = this.ns0 * adjust_lon(lon - this.long0);
	  var x = rh1 * Math.sin(theta) + this.x0;
	  var y = this.rh - rh1 * Math.cos(theta) + this.y0;

	  p.x = x;
	  p.y = y;
	  return p;
	}

	function inverse$13(p) {
	  var rh1, qs, con, theta, lon, lat;

	  p.x -= this.x0;
	  p.y = this.rh - p.y + this.y0;
	  if (this.ns0 >= 0) {
	    rh1 = Math.sqrt(p.x * p.x + p.y * p.y);
	    con = 1;
	  }
	  else {
	    rh1 = -Math.sqrt(p.x * p.x + p.y * p.y);
	    con = -1;
	  }
	  theta = 0;
	  if (rh1 !== 0) {
	    theta = Math.atan2(con * p.x, con * p.y);
	  }
	  con = rh1 * this.ns0 / this.a;
	  if (this.sphere) {
	    lat = Math.asin((this.c - con * con) / (2 * this.ns0));
	  }
	  else {
	    qs = (this.c - con * con) / this.ns0;
	    lat = this.phi1z(this.e3, qs);
	  }

	  lon = adjust_lon(theta / this.ns0 + this.long0);
	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	/* Function to compute phi1, the latitude for the inverse of the
	   Albers Conical Equal-Area projection.
	-------------------------------------------*/
	function phi1z(eccent, qs) {
	  var sinphi, cosphi, con, com, dphi;
	  var phi = asinz(0.5 * qs);
	  if (eccent < EPSLN) {
	    return phi;
	  }

	  var eccnts = eccent * eccent;
	  for (var i = 1; i <= 25; i++) {
	    sinphi = Math.sin(phi);
	    cosphi = Math.cos(phi);
	    con = eccent * sinphi;
	    com = 1 - con * con;
	    dphi = 0.5 * com * com / cosphi * (qs / (1 - eccnts) - sinphi / com + 0.5 / eccent * Math.log((1 - con) / (1 + con)));
	    phi = phi + dphi;
	    if (Math.abs(dphi) <= 1e-7) {
	      return phi;
	    }
	  }
	  return null;
	}

	var names$15 = ["Albers_Conic_Equal_Area", "Albers", "aea"];
	var aea = {
	  init: init$14,
	  forward: forward$13,
	  inverse: inverse$13,
	  names: names$15,
	  phi1z: phi1z
	};

	/*
	  reference:
	    Wolfram Mathworld "Gnomonic Projection"
	    http://mathworld.wolfram.com/GnomonicProjection.html
	    Accessed: 12th November 2009
	  */
	function init$15() {

	  /* Place parameters in static storage for common use
	      -------------------------------------------------*/
	  this.sin_p14 = Math.sin(this.lat0);
	  this.cos_p14 = Math.cos(this.lat0);
	  // Approximation for projecting points to the horizon (infinity)
	  this.infinity_dist = 1000 * this.a;
	  this.rc = 1;
	}

	/* Gnomonic forward equations--mapping lat,long to x,y
	    ---------------------------------------------------*/
	function forward$14(p) {
	  var sinphi, cosphi; /* sin and cos value        */
	  var dlon; /* delta longitude value      */
	  var coslon; /* cos of longitude        */
	  var ksp; /* scale factor          */
	  var g;
	  var x, y;
	  var lon = p.x;
	  var lat = p.y;
	  /* Forward equations
	      -----------------*/
	  dlon = adjust_lon(lon - this.long0);

	  sinphi = Math.sin(lat);
	  cosphi = Math.cos(lat);

	  coslon = Math.cos(dlon);
	  g = this.sin_p14 * sinphi + this.cos_p14 * cosphi * coslon;
	  ksp = 1;
	  if ((g > 0) || (Math.abs(g) <= EPSLN)) {
	    x = this.x0 + this.a * ksp * cosphi * Math.sin(dlon) / g;
	    y = this.y0 + this.a * ksp * (this.cos_p14 * sinphi - this.sin_p14 * cosphi * coslon) / g;
	  }
	  else {

	    // Point is in the opposing hemisphere and is unprojectable
	    // We still need to return a reasonable point, so we project
	    // to infinity, on a bearing
	    // equivalent to the northern hemisphere equivalent
	    // This is a reasonable approximation for short shapes and lines that
	    // straddle the horizon.

	    x = this.x0 + this.infinity_dist * cosphi * Math.sin(dlon);
	    y = this.y0 + this.infinity_dist * (this.cos_p14 * sinphi - this.sin_p14 * cosphi * coslon);

	  }
	  p.x = x;
	  p.y = y;
	  return p;
	}

	function inverse$14(p) {
	  var rh; /* Rho */
	  var sinc, cosc;
	  var c;
	  var lon, lat;

	  /* Inverse equations
	      -----------------*/
	  p.x = (p.x - this.x0) / this.a;
	  p.y = (p.y - this.y0) / this.a;

	  p.x /= this.k0;
	  p.y /= this.k0;

	  if ((rh = Math.sqrt(p.x * p.x + p.y * p.y))) {
	    c = Math.atan2(rh, this.rc);
	    sinc = Math.sin(c);
	    cosc = Math.cos(c);

	    lat = asinz(cosc * this.sin_p14 + (p.y * sinc * this.cos_p14) / rh);
	    lon = Math.atan2(p.x * sinc, rh * this.cos_p14 * cosc - p.y * this.sin_p14 * sinc);
	    lon = adjust_lon(this.long0 + lon);
	  }
	  else {
	    lat = this.phic0;
	    lon = 0;
	  }

	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$16 = ["gnom"];
	var gnom = {
	  init: init$15,
	  forward: forward$14,
	  inverse: inverse$14,
	  names: names$16
	};

	var iqsfnz = function(eccent, q) {
	  var temp = 1 - (1 - eccent * eccent) / (2 * eccent) * Math.log((1 - eccent) / (1 + eccent));
	  if (Math.abs(Math.abs(q) - temp) < 1.0E-6) {
	    if (q < 0) {
	      return (-1 * HALF_PI);
	    }
	    else {
	      return HALF_PI;
	    }
	  }
	  //var phi = 0.5* q/(1-eccent*eccent);
	  var phi = Math.asin(0.5 * q);
	  var dphi;
	  var sin_phi;
	  var cos_phi;
	  var con;
	  for (var i = 0; i < 30; i++) {
	    sin_phi = Math.sin(phi);
	    cos_phi = Math.cos(phi);
	    con = eccent * sin_phi;
	    dphi = Math.pow(1 - con * con, 2) / (2 * cos_phi) * (q / (1 - eccent * eccent) - sin_phi / (1 - con * con) + 0.5 / eccent * Math.log((1 - con) / (1 + con)));
	    phi += dphi;
	    if (Math.abs(dphi) <= 0.0000000001) {
	      return phi;
	    }
	  }

	  //console.log("IQSFN-CONV:Latitude failed to converge after 30 iterations");
	  return NaN;
	};

	/*
	  reference:
	    "Cartographic Projection Procedures for the UNIX Environment-
	    A User's Manual" by Gerald I. Evenden,
	    USGS Open File Report 90-284and Release 4 Interim Reports (2003)
	*/
	function init$16() {
	  //no-op
	  if (!this.sphere) {
	    this.k0 = msfnz(this.e, Math.sin(this.lat_ts), Math.cos(this.lat_ts));
	  }
	}

	/* Cylindrical Equal Area forward equations--mapping lat,long to x,y
	    ------------------------------------------------------------*/
	function forward$15(p) {
	  var lon = p.x;
	  var lat = p.y;
	  var x, y;
	  /* Forward equations
	      -----------------*/
	  var dlon = adjust_lon(lon - this.long0);
	  if (this.sphere) {
	    x = this.x0 + this.a * dlon * Math.cos(this.lat_ts);
	    y = this.y0 + this.a * Math.sin(lat) / Math.cos(this.lat_ts);
	  }
	  else {
	    var qs = qsfnz(this.e, Math.sin(lat));
	    x = this.x0 + this.a * this.k0 * dlon;
	    y = this.y0 + this.a * qs * 0.5 / this.k0;
	  }

	  p.x = x;
	  p.y = y;
	  return p;
	}

	/* Cylindrical Equal Area inverse equations--mapping x,y to lat/long
	    ------------------------------------------------------------*/
	function inverse$15(p) {
	  p.x -= this.x0;
	  p.y -= this.y0;
	  var lon, lat;

	  if (this.sphere) {
	    lon = adjust_lon(this.long0 + (p.x / this.a) / Math.cos(this.lat_ts));
	    lat = Math.asin((p.y / this.a) * Math.cos(this.lat_ts));
	  }
	  else {
	    lat = iqsfnz(this.e, 2 * p.y * this.k0 / this.a);
	    lon = adjust_lon(this.long0 + p.x / (this.a * this.k0));
	  }

	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$17 = ["cea"];
	var cea = {
	  init: init$16,
	  forward: forward$15,
	  inverse: inverse$15,
	  names: names$17
	};

	function init$17() {

	  this.x0 = this.x0 || 0;
	  this.y0 = this.y0 || 0;
	  this.lat0 = this.lat0 || 0;
	  this.long0 = this.long0 || 0;
	  this.lat_ts = this.lat_ts || 0;
	  this.title = this.title || "Equidistant Cylindrical (Plate Carre)";

	  this.rc = Math.cos(this.lat_ts);
	}

	// forward equations--mapping lat,long to x,y
	// -----------------------------------------------------------------
	function forward$16(p) {

	  var lon = p.x;
	  var lat = p.y;

	  var dlon = adjust_lon(lon - this.long0);
	  var dlat = adjust_lat(lat - this.lat0);
	  p.x = this.x0 + (this.a * dlon * this.rc);
	  p.y = this.y0 + (this.a * dlat);
	  return p;
	}

	// inverse equations--mapping x,y to lat/long
	// -----------------------------------------------------------------
	function inverse$16(p) {

	  var x = p.x;
	  var y = p.y;

	  p.x = adjust_lon(this.long0 + ((x - this.x0) / (this.a * this.rc)));
	  p.y = adjust_lat(this.lat0 + ((y - this.y0) / (this.a)));
	  return p;
	}

	var names$18 = ["Equirectangular", "Equidistant_Cylindrical", "eqc"];
	var eqc = {
	  init: init$17,
	  forward: forward$16,
	  inverse: inverse$16,
	  names: names$18
	};

	var MAX_ITER$2 = 20;

	function init$18() {
	  /* Place parameters in static storage for common use
	      -------------------------------------------------*/
	  this.temp = this.b / this.a;
	  this.es = 1 - Math.pow(this.temp, 2); // devait etre dans tmerc.js mais n y est pas donc je commente sinon retour de valeurs nulles
	  this.e = Math.sqrt(this.es);
	  this.e0 = e0fn(this.es);
	  this.e1 = e1fn(this.es);
	  this.e2 = e2fn(this.es);
	  this.e3 = e3fn(this.es);
	  this.ml0 = this.a * mlfn(this.e0, this.e1, this.e2, this.e3, this.lat0); //si que des zeros le calcul ne se fait pas
	}

	/* Polyconic forward equations--mapping lat,long to x,y
	    ---------------------------------------------------*/
	function forward$17(p) {
	  var lon = p.x;
	  var lat = p.y;
	  var x, y, el;
	  var dlon = adjust_lon(lon - this.long0);
	  el = dlon * Math.sin(lat);
	  if (this.sphere) {
	    if (Math.abs(lat) <= EPSLN) {
	      x = this.a * dlon;
	      y = -1 * this.a * this.lat0;
	    }
	    else {
	      x = this.a * Math.sin(el) / Math.tan(lat);
	      y = this.a * (adjust_lat(lat - this.lat0) + (1 - Math.cos(el)) / Math.tan(lat));
	    }
	  }
	  else {
	    if (Math.abs(lat) <= EPSLN) {
	      x = this.a * dlon;
	      y = -1 * this.ml0;
	    }
	    else {
	      var nl = gN(this.a, this.e, Math.sin(lat)) / Math.tan(lat);
	      x = nl * Math.sin(el);
	      y = this.a * mlfn(this.e0, this.e1, this.e2, this.e3, lat) - this.ml0 + nl * (1 - Math.cos(el));
	    }

	  }
	  p.x = x + this.x0;
	  p.y = y + this.y0;
	  return p;
	}

	/* Inverse equations
	  -----------------*/
	function inverse$17(p) {
	  var lon, lat, x, y, i;
	  var al, bl;
	  var phi, dphi;
	  x = p.x - this.x0;
	  y = p.y - this.y0;

	  if (this.sphere) {
	    if (Math.abs(y + this.a * this.lat0) <= EPSLN) {
	      lon = adjust_lon(x / this.a + this.long0);
	      lat = 0;
	    }
	    else {
	      al = this.lat0 + y / this.a;
	      bl = x * x / this.a / this.a + al * al;
	      phi = al;
	      var tanphi;
	      for (i = MAX_ITER$2; i; --i) {
	        tanphi = Math.tan(phi);
	        dphi = -1 * (al * (phi * tanphi + 1) - phi - 0.5 * (phi * phi + bl) * tanphi) / ((phi - al) / tanphi - 1);
	        phi += dphi;
	        if (Math.abs(dphi) <= EPSLN) {
	          lat = phi;
	          break;
	        }
	      }
	      lon = adjust_lon(this.long0 + (Math.asin(x * Math.tan(phi) / this.a)) / Math.sin(lat));
	    }
	  }
	  else {
	    if (Math.abs(y + this.ml0) <= EPSLN) {
	      lat = 0;
	      lon = adjust_lon(this.long0 + x / this.a);
	    }
	    else {

	      al = (this.ml0 + y) / this.a;
	      bl = x * x / this.a / this.a + al * al;
	      phi = al;
	      var cl, mln, mlnp, ma;
	      var con;
	      for (i = MAX_ITER$2; i; --i) {
	        con = this.e * Math.sin(phi);
	        cl = Math.sqrt(1 - con * con) * Math.tan(phi);
	        mln = this.a * mlfn(this.e0, this.e1, this.e2, this.e3, phi);
	        mlnp = this.e0 - 2 * this.e1 * Math.cos(2 * phi) + 4 * this.e2 * Math.cos(4 * phi) - 6 * this.e3 * Math.cos(6 * phi);
	        ma = mln / this.a;
	        dphi = (al * (cl * ma + 1) - ma - 0.5 * cl * (ma * ma + bl)) / (this.es * Math.sin(2 * phi) * (ma * ma + bl - 2 * al * ma) / (4 * cl) + (al - ma) * (cl * mlnp - 2 / Math.sin(2 * phi)) - mlnp);
	        phi -= dphi;
	        if (Math.abs(dphi) <= EPSLN) {
	          lat = phi;
	          break;
	        }
	      }

	      //lat=phi4z(this.e,this.e0,this.e1,this.e2,this.e3,al,bl,0,0);
	      cl = Math.sqrt(1 - this.es * Math.pow(Math.sin(lat), 2)) * Math.tan(lat);
	      lon = adjust_lon(this.long0 + Math.asin(x * cl / this.a) / Math.sin(lat));
	    }
	  }

	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$19 = ["Polyconic", "poly"];
	var poly = {
	  init: init$18,
	  forward: forward$17,
	  inverse: inverse$17,
	  names: names$19
	};

	/*
	  reference
	    Department of Land and Survey Technical Circular 1973/32
	      http://www.linz.govt.nz/docs/miscellaneous/nz-map-definition.pdf
	    OSG Technical Report 4.1
	      http://www.linz.govt.nz/docs/miscellaneous/nzmg.pdf
	  */

	/**
	 * iterations: Number of iterations to refine inverse transform.
	 *     0 -> km accuracy
	 *     1 -> m accuracy -- suitable for most mapping applications
	 *     2 -> mm accuracy
	 */


	function init$19() {
	  this.A = [];
	  this.A[1] = 0.6399175073;
	  this.A[2] = -0.1358797613;
	  this.A[3] = 0.063294409;
	  this.A[4] = -0.02526853;
	  this.A[5] = 0.0117879;
	  this.A[6] = -0.0055161;
	  this.A[7] = 0.0026906;
	  this.A[8] = -0.001333;
	  this.A[9] = 0.00067;
	  this.A[10] = -0.00034;

	  this.B_re = [];
	  this.B_im = [];
	  this.B_re[1] = 0.7557853228;
	  this.B_im[1] = 0;
	  this.B_re[2] = 0.249204646;
	  this.B_im[2] = 0.003371507;
	  this.B_re[3] = -0.001541739;
	  this.B_im[3] = 0.041058560;
	  this.B_re[4] = -0.10162907;
	  this.B_im[4] = 0.01727609;
	  this.B_re[5] = -0.26623489;
	  this.B_im[5] = -0.36249218;
	  this.B_re[6] = -0.6870983;
	  this.B_im[6] = -1.1651967;

	  this.C_re = [];
	  this.C_im = [];
	  this.C_re[1] = 1.3231270439;
	  this.C_im[1] = 0;
	  this.C_re[2] = -0.577245789;
	  this.C_im[2] = -0.007809598;
	  this.C_re[3] = 0.508307513;
	  this.C_im[3] = -0.112208952;
	  this.C_re[4] = -0.15094762;
	  this.C_im[4] = 0.18200602;
	  this.C_re[5] = 1.01418179;
	  this.C_im[5] = 1.64497696;
	  this.C_re[6] = 1.9660549;
	  this.C_im[6] = 2.5127645;

	  this.D = [];
	  this.D[1] = 1.5627014243;
	  this.D[2] = 0.5185406398;
	  this.D[3] = -0.03333098;
	  this.D[4] = -0.1052906;
	  this.D[5] = -0.0368594;
	  this.D[6] = 0.007317;
	  this.D[7] = 0.01220;
	  this.D[8] = 0.00394;
	  this.D[9] = -0.0013;
	}

	/**
	    New Zealand Map Grid Forward  - long/lat to x/y
	    long/lat in radians
	  */
	function forward$18(p) {
	  var n;
	  var lon = p.x;
	  var lat = p.y;

	  var delta_lat = lat - this.lat0;
	  var delta_lon = lon - this.long0;

	  // 1. Calculate d_phi and d_psi    ...                          // and d_lambda
	  // For this algorithm, delta_latitude is in seconds of arc x 10-5, so we need to scale to those units. Longitude is radians.
	  var d_phi = delta_lat / SEC_TO_RAD * 1E-5;
	  var d_lambda = delta_lon;
	  var d_phi_n = 1; // d_phi^0

	  var d_psi = 0;
	  for (n = 1; n <= 10; n++) {
	    d_phi_n = d_phi_n * d_phi;
	    d_psi = d_psi + this.A[n] * d_phi_n;
	  }

	  // 2. Calculate theta
	  var th_re = d_psi;
	  var th_im = d_lambda;

	  // 3. Calculate z
	  var th_n_re = 1;
	  var th_n_im = 0; // theta^0
	  var th_n_re1;
	  var th_n_im1;

	  var z_re = 0;
	  var z_im = 0;
	  for (n = 1; n <= 6; n++) {
	    th_n_re1 = th_n_re * th_re - th_n_im * th_im;
	    th_n_im1 = th_n_im * th_re + th_n_re * th_im;
	    th_n_re = th_n_re1;
	    th_n_im = th_n_im1;
	    z_re = z_re + this.B_re[n] * th_n_re - this.B_im[n] * th_n_im;
	    z_im = z_im + this.B_im[n] * th_n_re + this.B_re[n] * th_n_im;
	  }

	  // 4. Calculate easting and northing
	  p.x = (z_im * this.a) + this.x0;
	  p.y = (z_re * this.a) + this.y0;

	  return p;
	}

	/**
	    New Zealand Map Grid Inverse  -  x/y to long/lat
	  */
	function inverse$18(p) {
	  var n;
	  var x = p.x;
	  var y = p.y;

	  var delta_x = x - this.x0;
	  var delta_y = y - this.y0;

	  // 1. Calculate z
	  var z_re = delta_y / this.a;
	  var z_im = delta_x / this.a;

	  // 2a. Calculate theta - first approximation gives km accuracy
	  var z_n_re = 1;
	  var z_n_im = 0; // z^0
	  var z_n_re1;
	  var z_n_im1;

	  var th_re = 0;
	  var th_im = 0;
	  for (n = 1; n <= 6; n++) {
	    z_n_re1 = z_n_re * z_re - z_n_im * z_im;
	    z_n_im1 = z_n_im * z_re + z_n_re * z_im;
	    z_n_re = z_n_re1;
	    z_n_im = z_n_im1;
	    th_re = th_re + this.C_re[n] * z_n_re - this.C_im[n] * z_n_im;
	    th_im = th_im + this.C_im[n] * z_n_re + this.C_re[n] * z_n_im;
	  }

	  // 2b. Iterate to refine the accuracy of the calculation
	  //        0 iterations gives km accuracy
	  //        1 iteration gives m accuracy -- good enough for most mapping applications
	  //        2 iterations bives mm accuracy
	  for (var i = 0; i < this.iterations; i++) {
	    var th_n_re = th_re;
	    var th_n_im = th_im;
	    var th_n_re1;
	    var th_n_im1;

	    var num_re = z_re;
	    var num_im = z_im;
	    for (n = 2; n <= 6; n++) {
	      th_n_re1 = th_n_re * th_re - th_n_im * th_im;
	      th_n_im1 = th_n_im * th_re + th_n_re * th_im;
	      th_n_re = th_n_re1;
	      th_n_im = th_n_im1;
	      num_re = num_re + (n - 1) * (this.B_re[n] * th_n_re - this.B_im[n] * th_n_im);
	      num_im = num_im + (n - 1) * (this.B_im[n] * th_n_re + this.B_re[n] * th_n_im);
	    }

	    th_n_re = 1;
	    th_n_im = 0;
	    var den_re = this.B_re[1];
	    var den_im = this.B_im[1];
	    for (n = 2; n <= 6; n++) {
	      th_n_re1 = th_n_re * th_re - th_n_im * th_im;
	      th_n_im1 = th_n_im * th_re + th_n_re * th_im;
	      th_n_re = th_n_re1;
	      th_n_im = th_n_im1;
	      den_re = den_re + n * (this.B_re[n] * th_n_re - this.B_im[n] * th_n_im);
	      den_im = den_im + n * (this.B_im[n] * th_n_re + this.B_re[n] * th_n_im);
	    }

	    // Complex division
	    var den2 = den_re * den_re + den_im * den_im;
	    th_re = (num_re * den_re + num_im * den_im) / den2;
	    th_im = (num_im * den_re - num_re * den_im) / den2;
	  }

	  // 3. Calculate d_phi              ...                                    // and d_lambda
	  var d_psi = th_re;
	  var d_lambda = th_im;
	  var d_psi_n = 1; // d_psi^0

	  var d_phi = 0;
	  for (n = 1; n <= 9; n++) {
	    d_psi_n = d_psi_n * d_psi;
	    d_phi = d_phi + this.D[n] * d_psi_n;
	  }

	  // 4. Calculate latitude and longitude
	  // d_phi is calcuated in second of arc * 10^-5, so we need to scale back to radians. d_lambda is in radians.
	  var lat = this.lat0 + (d_phi * SEC_TO_RAD * 1E5);
	  var lon = this.long0 + d_lambda;

	  p.x = lon;
	  p.y = lat;

	  return p;
	}

	var names$20 = ["New_Zealand_Map_Grid", "nzmg"];
	var nzmg = {
	  init: init$19,
	  forward: forward$18,
	  inverse: inverse$18,
	  names: names$20
	};

	/*
	  reference
	    "New Equal-Area Map Projections for Noncircular Regions", John P. Snyder,
	    The American Cartographer, Vol 15, No. 4, October 1988, pp. 341-355.
	  */


	/* Initialize the Miller Cylindrical projection
	  -------------------------------------------*/
	function init$20() {
	  //no-op
	}

	/* Miller Cylindrical forward equations--mapping lat,long to x,y
	    ------------------------------------------------------------*/
	function forward$19(p) {
	  var lon = p.x;
	  var lat = p.y;
	  /* Forward equations
	      -----------------*/
	  var dlon = adjust_lon(lon - this.long0);
	  var x = this.x0 + this.a * dlon;
	  var y = this.y0 + this.a * Math.log(Math.tan((Math.PI / 4) + (lat / 2.5))) * 1.25;

	  p.x = x;
	  p.y = y;
	  return p;
	}

	/* Miller Cylindrical inverse equations--mapping x,y to lat/long
	    ------------------------------------------------------------*/
	function inverse$19(p) {
	  p.x -= this.x0;
	  p.y -= this.y0;

	  var lon = adjust_lon(this.long0 + p.x / this.a);
	  var lat = 2.5 * (Math.atan(Math.exp(0.8 * p.y / this.a)) - Math.PI / 4);

	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$21 = ["Miller_Cylindrical", "mill"];
	var mill = {
	  init: init$20,
	  forward: forward$19,
	  inverse: inverse$19,
	  names: names$21
	};

	var MAX_ITER$3 = 20;
	function init$21() {
	  /* Place parameters in static storage for common use
	    -------------------------------------------------*/


	  if (!this.sphere) {
	    this.en = pj_enfn(this.es);
	  }
	  else {
	    this.n = 1;
	    this.m = 0;
	    this.es = 0;
	    this.C_y = Math.sqrt((this.m + 1) / this.n);
	    this.C_x = this.C_y / (this.m + 1);
	  }

	}

	/* Sinusoidal forward equations--mapping lat,long to x,y
	  -----------------------------------------------------*/
	function forward$20(p) {
	  var x, y;
	  var lon = p.x;
	  var lat = p.y;
	  /* Forward equations
	    -----------------*/
	  lon = adjust_lon(lon - this.long0);

	  if (this.sphere) {
	    if (!this.m) {
	      lat = this.n !== 1 ? Math.asin(this.n * Math.sin(lat)) : lat;
	    }
	    else {
	      var k = this.n * Math.sin(lat);
	      for (var i = MAX_ITER$3; i; --i) {
	        var V = (this.m * lat + Math.sin(lat) - k) / (this.m + Math.cos(lat));
	        lat -= V;
	        if (Math.abs(V) < EPSLN) {
	          break;
	        }
	      }
	    }
	    x = this.a * this.C_x * lon * (this.m + Math.cos(lat));
	    y = this.a * this.C_y * lat;

	  }
	  else {

	    var s = Math.sin(lat);
	    var c = Math.cos(lat);
	    y = this.a * pj_mlfn(lat, s, c, this.en);
	    x = this.a * lon * c / Math.sqrt(1 - this.es * s * s);
	  }

	  p.x = x;
	  p.y = y;
	  return p;
	}

	function inverse$20(p) {
	  var lat, temp, lon, s;

	  p.x -= this.x0;
	  lon = p.x / this.a;
	  p.y -= this.y0;
	  lat = p.y / this.a;

	  if (this.sphere) {
	    lat /= this.C_y;
	    lon = lon / (this.C_x * (this.m + Math.cos(lat)));
	    if (this.m) {
	      lat = asinz((this.m * lat + Math.sin(lat)) / this.n);
	    }
	    else if (this.n !== 1) {
	      lat = asinz(Math.sin(lat) / this.n);
	    }
	    lon = adjust_lon(lon + this.long0);
	    lat = adjust_lat(lat);
	  }
	  else {
	    lat = pj_inv_mlfn(p.y / this.a, this.es, this.en);
	    s = Math.abs(lat);
	    if (s < HALF_PI) {
	      s = Math.sin(lat);
	      temp = this.long0 + p.x * Math.sqrt(1 - this.es * s * s) / (this.a * Math.cos(lat));
	      //temp = this.long0 + p.x / (this.a * Math.cos(lat));
	      lon = adjust_lon(temp);
	    }
	    else if ((s - EPSLN) < HALF_PI) {
	      lon = this.long0;
	    }
	  }
	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$22 = ["Sinusoidal", "sinu"];
	var sinu = {
	  init: init$21,
	  forward: forward$20,
	  inverse: inverse$20,
	  names: names$22
	};

	function init$22() {}
	/* Mollweide forward equations--mapping lat,long to x,y
	    ----------------------------------------------------*/
	function forward$21(p) {

	  /* Forward equations
	      -----------------*/
	  var lon = p.x;
	  var lat = p.y;

	  var delta_lon = adjust_lon(lon - this.long0);
	  var theta = lat;
	  var con = Math.PI * Math.sin(lat);

	  /* Iterate using the Newton-Raphson method to find theta
	      -----------------------------------------------------*/
	  while (true) {
	    var delta_theta = -(theta + Math.sin(theta) - con) / (1 + Math.cos(theta));
	    theta += delta_theta;
	    if (Math.abs(delta_theta) < EPSLN) {
	      break;
	    }
	  }
	  theta /= 2;

	  /* If the latitude is 90 deg, force the x coordinate to be "0 + false easting"
	       this is done here because of precision problems with "cos(theta)"
	       --------------------------------------------------------------------------*/
	  if (Math.PI / 2 - Math.abs(lat) < EPSLN) {
	    delta_lon = 0;
	  }
	  var x = 0.900316316158 * this.a * delta_lon * Math.cos(theta) + this.x0;
	  var y = 1.4142135623731 * this.a * Math.sin(theta) + this.y0;

	  p.x = x;
	  p.y = y;
	  return p;
	}

	function inverse$21(p) {
	  var theta;
	  var arg;

	  /* Inverse equations
	      -----------------*/
	  p.x -= this.x0;
	  p.y -= this.y0;
	  arg = p.y / (1.4142135623731 * this.a);

	  /* Because of division by zero problems, 'arg' can not be 1.  Therefore
	       a number very close to one is used instead.
	       -------------------------------------------------------------------*/
	  if (Math.abs(arg) > 0.999999999999) {
	    arg = 0.999999999999;
	  }
	  theta = Math.asin(arg);
	  var lon = adjust_lon(this.long0 + (p.x / (0.900316316158 * this.a * Math.cos(theta))));
	  if (lon < (-Math.PI)) {
	    lon = -Math.PI;
	  }
	  if (lon > Math.PI) {
	    lon = Math.PI;
	  }
	  arg = (2 * theta + Math.sin(2 * theta)) / Math.PI;
	  if (Math.abs(arg) > 1) {
	    arg = 1;
	  }
	  var lat = Math.asin(arg);

	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$23 = ["Mollweide", "moll"];
	var moll = {
	  init: init$22,
	  forward: forward$21,
	  inverse: inverse$21,
	  names: names$23
	};

	function init$23() {

	  /* Place parameters in static storage for common use
	      -------------------------------------------------*/
	  // Standard Parallels cannot be equal and on opposite sides of the equator
	  if (Math.abs(this.lat1 + this.lat2) < EPSLN) {
	    return;
	  }
	  this.lat2 = this.lat2 || this.lat1;
	  this.temp = this.b / this.a;
	  this.es = 1 - Math.pow(this.temp, 2);
	  this.e = Math.sqrt(this.es);
	  this.e0 = e0fn(this.es);
	  this.e1 = e1fn(this.es);
	  this.e2 = e2fn(this.es);
	  this.e3 = e3fn(this.es);

	  this.sinphi = Math.sin(this.lat1);
	  this.cosphi = Math.cos(this.lat1);

	  this.ms1 = msfnz(this.e, this.sinphi, this.cosphi);
	  this.ml1 = mlfn(this.e0, this.e1, this.e2, this.e3, this.lat1);

	  if (Math.abs(this.lat1 - this.lat2) < EPSLN) {
	    this.ns = this.sinphi;
	  }
	  else {
	    this.sinphi = Math.sin(this.lat2);
	    this.cosphi = Math.cos(this.lat2);
	    this.ms2 = msfnz(this.e, this.sinphi, this.cosphi);
	    this.ml2 = mlfn(this.e0, this.e1, this.e2, this.e3, this.lat2);
	    this.ns = (this.ms1 - this.ms2) / (this.ml2 - this.ml1);
	  }
	  this.g = this.ml1 + this.ms1 / this.ns;
	  this.ml0 = mlfn(this.e0, this.e1, this.e2, this.e3, this.lat0);
	  this.rh = this.a * (this.g - this.ml0);
	}

	/* Equidistant Conic forward equations--mapping lat,long to x,y
	  -----------------------------------------------------------*/
	function forward$22(p) {
	  var lon = p.x;
	  var lat = p.y;
	  var rh1;

	  /* Forward equations
	      -----------------*/
	  if (this.sphere) {
	    rh1 = this.a * (this.g - lat);
	  }
	  else {
	    var ml = mlfn(this.e0, this.e1, this.e2, this.e3, lat);
	    rh1 = this.a * (this.g - ml);
	  }
	  var theta = this.ns * adjust_lon(lon - this.long0);
	  var x = this.x0 + rh1 * Math.sin(theta);
	  var y = this.y0 + this.rh - rh1 * Math.cos(theta);
	  p.x = x;
	  p.y = y;
	  return p;
	}

	/* Inverse equations
	  -----------------*/
	function inverse$22(p) {
	  p.x -= this.x0;
	  p.y = this.rh - p.y + this.y0;
	  var con, rh1, lat, lon;
	  if (this.ns >= 0) {
	    rh1 = Math.sqrt(p.x * p.x + p.y * p.y);
	    con = 1;
	  }
	  else {
	    rh1 = -Math.sqrt(p.x * p.x + p.y * p.y);
	    con = -1;
	  }
	  var theta = 0;
	  if (rh1 !== 0) {
	    theta = Math.atan2(con * p.x, con * p.y);
	  }

	  if (this.sphere) {
	    lon = adjust_lon(this.long0 + theta / this.ns);
	    lat = adjust_lat(this.g - rh1 / this.a);
	    p.x = lon;
	    p.y = lat;
	    return p;
	  }
	  else {
	    var ml = this.g - rh1 / this.a;
	    lat = imlfn(ml, this.e0, this.e1, this.e2, this.e3);
	    lon = adjust_lon(this.long0 + theta / this.ns);
	    p.x = lon;
	    p.y = lat;
	    return p;
	  }

	}

	var names$24 = ["Equidistant_Conic", "eqdc"];
	var eqdc = {
	  init: init$23,
	  forward: forward$22,
	  inverse: inverse$22,
	  names: names$24
	};

	/* Initialize the Van Der Grinten projection
	  ----------------------------------------*/
	function init$24() {
	  //this.R = 6370997; //Radius of earth
	  this.R = this.a;
	}

	function forward$23(p) {

	  var lon = p.x;
	  var lat = p.y;

	  /* Forward equations
	    -----------------*/
	  var dlon = adjust_lon(lon - this.long0);
	  var x, y;

	  if (Math.abs(lat) <= EPSLN) {
	    x = this.x0 + this.R * dlon;
	    y = this.y0;
	  }
	  var theta = asinz(2 * Math.abs(lat / Math.PI));
	  if ((Math.abs(dlon) <= EPSLN) || (Math.abs(Math.abs(lat) - HALF_PI) <= EPSLN)) {
	    x = this.x0;
	    if (lat >= 0) {
	      y = this.y0 + Math.PI * this.R * Math.tan(0.5 * theta);
	    }
	    else {
	      y = this.y0 + Math.PI * this.R * -Math.tan(0.5 * theta);
	    }
	    //  return(OK);
	  }
	  var al = 0.5 * Math.abs((Math.PI / dlon) - (dlon / Math.PI));
	  var asq = al * al;
	  var sinth = Math.sin(theta);
	  var costh = Math.cos(theta);

	  var g = costh / (sinth + costh - 1);
	  var gsq = g * g;
	  var m = g * (2 / sinth - 1);
	  var msq = m * m;
	  var con = Math.PI * this.R * (al * (g - msq) + Math.sqrt(asq * (g - msq) * (g - msq) - (msq + asq) * (gsq - msq))) / (msq + asq);
	  if (dlon < 0) {
	    con = -con;
	  }
	  x = this.x0 + con;
	  //con = Math.abs(con / (Math.PI * this.R));
	  var q = asq + g;
	  con = Math.PI * this.R * (m * q - al * Math.sqrt((msq + asq) * (asq + 1) - q * q)) / (msq + asq);
	  if (lat >= 0) {
	    //y = this.y0 + Math.PI * this.R * Math.sqrt(1 - con * con - 2 * al * con);
	    y = this.y0 + con;
	  }
	  else {
	    //y = this.y0 - Math.PI * this.R * Math.sqrt(1 - con * con - 2 * al * con);
	    y = this.y0 - con;
	  }
	  p.x = x;
	  p.y = y;
	  return p;
	}

	/* Van Der Grinten inverse equations--mapping x,y to lat/long
	  ---------------------------------------------------------*/
	function inverse$23(p) {
	  var lon, lat;
	  var xx, yy, xys, c1, c2, c3;
	  var a1;
	  var m1;
	  var con;
	  var th1;
	  var d;

	  /* inverse equations
	    -----------------*/
	  p.x -= this.x0;
	  p.y -= this.y0;
	  con = Math.PI * this.R;
	  xx = p.x / con;
	  yy = p.y / con;
	  xys = xx * xx + yy * yy;
	  c1 = -Math.abs(yy) * (1 + xys);
	  c2 = c1 - 2 * yy * yy + xx * xx;
	  c3 = -2 * c1 + 1 + 2 * yy * yy + xys * xys;
	  d = yy * yy / c3 + (2 * c2 * c2 * c2 / c3 / c3 / c3 - 9 * c1 * c2 / c3 / c3) / 27;
	  a1 = (c1 - c2 * c2 / 3 / c3) / c3;
	  m1 = 2 * Math.sqrt(-a1 / 3);
	  con = ((3 * d) / a1) / m1;
	  if (Math.abs(con) > 1) {
	    if (con >= 0) {
	      con = 1;
	    }
	    else {
	      con = -1;
	    }
	  }
	  th1 = Math.acos(con) / 3;
	  if (p.y >= 0) {
	    lat = (-m1 * Math.cos(th1 + Math.PI / 3) - c2 / 3 / c3) * Math.PI;
	  }
	  else {
	    lat = -(-m1 * Math.cos(th1 + Math.PI / 3) - c2 / 3 / c3) * Math.PI;
	  }

	  if (Math.abs(xx) < EPSLN) {
	    lon = this.long0;
	  }
	  else {
	    lon = adjust_lon(this.long0 + Math.PI * (xys - 1 + Math.sqrt(1 + 2 * (xx * xx - yy * yy) + xys * xys)) / 2 / xx);
	  }

	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$25 = ["Van_der_Grinten_I", "VanDerGrinten", "vandg"];
	var vandg = {
	  init: init$24,
	  forward: forward$23,
	  inverse: inverse$23,
	  names: names$25
	};

	function init$25() {
	  this.sin_p12 = Math.sin(this.lat0);
	  this.cos_p12 = Math.cos(this.lat0);
	}

	function forward$24(p) {
	  var lon = p.x;
	  var lat = p.y;
	  var sinphi = Math.sin(p.y);
	  var cosphi = Math.cos(p.y);
	  var dlon = adjust_lon(lon - this.long0);
	  var e0, e1, e2, e3, Mlp, Ml, tanphi, Nl1, Nl, psi, Az, G, H, GH, Hs, c, kp, cos_c, s, s2, s3, s4, s5;
	  if (this.sphere) {
	    if (Math.abs(this.sin_p12 - 1) <= EPSLN) {
	      //North Pole case
	      p.x = this.x0 + this.a * (HALF_PI - lat) * Math.sin(dlon);
	      p.y = this.y0 - this.a * (HALF_PI - lat) * Math.cos(dlon);
	      return p;
	    }
	    else if (Math.abs(this.sin_p12 + 1) <= EPSLN) {
	      //South Pole case
	      p.x = this.x0 + this.a * (HALF_PI + lat) * Math.sin(dlon);
	      p.y = this.y0 + this.a * (HALF_PI + lat) * Math.cos(dlon);
	      return p;
	    }
	    else {
	      //default case
	      cos_c = this.sin_p12 * sinphi + this.cos_p12 * cosphi * Math.cos(dlon);
	      c = Math.acos(cos_c);
	      kp = c / Math.sin(c);
	      p.x = this.x0 + this.a * kp * cosphi * Math.sin(dlon);
	      p.y = this.y0 + this.a * kp * (this.cos_p12 * sinphi - this.sin_p12 * cosphi * Math.cos(dlon));
	      return p;
	    }
	  }
	  else {
	    e0 = e0fn(this.es);
	    e1 = e1fn(this.es);
	    e2 = e2fn(this.es);
	    e3 = e3fn(this.es);
	    if (Math.abs(this.sin_p12 - 1) <= EPSLN) {
	      //North Pole case
	      Mlp = this.a * mlfn(e0, e1, e2, e3, HALF_PI);
	      Ml = this.a * mlfn(e0, e1, e2, e3, lat);
	      p.x = this.x0 + (Mlp - Ml) * Math.sin(dlon);
	      p.y = this.y0 - (Mlp - Ml) * Math.cos(dlon);
	      return p;
	    }
	    else if (Math.abs(this.sin_p12 + 1) <= EPSLN) {
	      //South Pole case
	      Mlp = this.a * mlfn(e0, e1, e2, e3, HALF_PI);
	      Ml = this.a * mlfn(e0, e1, e2, e3, lat);
	      p.x = this.x0 + (Mlp + Ml) * Math.sin(dlon);
	      p.y = this.y0 + (Mlp + Ml) * Math.cos(dlon);
	      return p;
	    }
	    else {
	      //Default case
	      tanphi = sinphi / cosphi;
	      Nl1 = gN(this.a, this.e, this.sin_p12);
	      Nl = gN(this.a, this.e, sinphi);
	      psi = Math.atan((1 - this.es) * tanphi + this.es * Nl1 * this.sin_p12 / (Nl * cosphi));
	      Az = Math.atan2(Math.sin(dlon), this.cos_p12 * Math.tan(psi) - this.sin_p12 * Math.cos(dlon));
	      if (Az === 0) {
	        s = Math.asin(this.cos_p12 * Math.sin(psi) - this.sin_p12 * Math.cos(psi));
	      }
	      else if (Math.abs(Math.abs(Az) - Math.PI) <= EPSLN) {
	        s = -Math.asin(this.cos_p12 * Math.sin(psi) - this.sin_p12 * Math.cos(psi));
	      }
	      else {
	        s = Math.asin(Math.sin(dlon) * Math.cos(psi) / Math.sin(Az));
	      }
	      G = this.e * this.sin_p12 / Math.sqrt(1 - this.es);
	      H = this.e * this.cos_p12 * Math.cos(Az) / Math.sqrt(1 - this.es);
	      GH = G * H;
	      Hs = H * H;
	      s2 = s * s;
	      s3 = s2 * s;
	      s4 = s3 * s;
	      s5 = s4 * s;
	      c = Nl1 * s * (1 - s2 * Hs * (1 - Hs) / 6 + s3 / 8 * GH * (1 - 2 * Hs) + s4 / 120 * (Hs * (4 - 7 * Hs) - 3 * G * G * (1 - 7 * Hs)) - s5 / 48 * GH);
	      p.x = this.x0 + c * Math.sin(Az);
	      p.y = this.y0 + c * Math.cos(Az);
	      return p;
	    }
	  }


	}

	function inverse$24(p) {
	  p.x -= this.x0;
	  p.y -= this.y0;
	  var rh, z, sinz, cosz, lon, lat, con, e0, e1, e2, e3, Mlp, M, N1, psi, Az, cosAz, tmp, A, B, D, Ee, F;
	  if (this.sphere) {
	    rh = Math.sqrt(p.x * p.x + p.y * p.y);
	    if (rh > (2 * HALF_PI * this.a)) {
	      return;
	    }
	    z = rh / this.a;

	    sinz = Math.sin(z);
	    cosz = Math.cos(z);

	    lon = this.long0;
	    if (Math.abs(rh) <= EPSLN) {
	      lat = this.lat0;
	    }
	    else {
	      lat = asinz(cosz * this.sin_p12 + (p.y * sinz * this.cos_p12) / rh);
	      con = Math.abs(this.lat0) - HALF_PI;
	      if (Math.abs(con) <= EPSLN) {
	        if (this.lat0 >= 0) {
	          lon = adjust_lon(this.long0 + Math.atan2(p.x, - p.y));
	        }
	        else {
	          lon = adjust_lon(this.long0 - Math.atan2(-p.x, p.y));
	        }
	      }
	      else {
	        /*con = cosz - this.sin_p12 * Math.sin(lat);
	        if ((Math.abs(con) < EPSLN) && (Math.abs(p.x) < EPSLN)) {
	          //no-op, just keep the lon value as is
	        } else {
	          var temp = Math.atan2((p.x * sinz * this.cos_p12), (con * rh));
	          lon = adjust_lon(this.long0 + Math.atan2((p.x * sinz * this.cos_p12), (con * rh)));
	        }*/
	        lon = adjust_lon(this.long0 + Math.atan2(p.x * sinz, rh * this.cos_p12 * cosz - p.y * this.sin_p12 * sinz));
	      }
	    }

	    p.x = lon;
	    p.y = lat;
	    return p;
	  }
	  else {
	    e0 = e0fn(this.es);
	    e1 = e1fn(this.es);
	    e2 = e2fn(this.es);
	    e3 = e3fn(this.es);
	    if (Math.abs(this.sin_p12 - 1) <= EPSLN) {
	      //North pole case
	      Mlp = this.a * mlfn(e0, e1, e2, e3, HALF_PI);
	      rh = Math.sqrt(p.x * p.x + p.y * p.y);
	      M = Mlp - rh;
	      lat = imlfn(M / this.a, e0, e1, e2, e3);
	      lon = adjust_lon(this.long0 + Math.atan2(p.x, - 1 * p.y));
	      p.x = lon;
	      p.y = lat;
	      return p;
	    }
	    else if (Math.abs(this.sin_p12 + 1) <= EPSLN) {
	      //South pole case
	      Mlp = this.a * mlfn(e0, e1, e2, e3, HALF_PI);
	      rh = Math.sqrt(p.x * p.x + p.y * p.y);
	      M = rh - Mlp;

	      lat = imlfn(M / this.a, e0, e1, e2, e3);
	      lon = adjust_lon(this.long0 + Math.atan2(p.x, p.y));
	      p.x = lon;
	      p.y = lat;
	      return p;
	    }
	    else {
	      //default case
	      rh = Math.sqrt(p.x * p.x + p.y * p.y);
	      Az = Math.atan2(p.x, p.y);
	      N1 = gN(this.a, this.e, this.sin_p12);
	      cosAz = Math.cos(Az);
	      tmp = this.e * this.cos_p12 * cosAz;
	      A = -tmp * tmp / (1 - this.es);
	      B = 3 * this.es * (1 - A) * this.sin_p12 * this.cos_p12 * cosAz / (1 - this.es);
	      D = rh / N1;
	      Ee = D - A * (1 + A) * Math.pow(D, 3) / 6 - B * (1 + 3 * A) * Math.pow(D, 4) / 24;
	      F = 1 - A * Ee * Ee / 2 - D * Ee * Ee * Ee / 6;
	      psi = Math.asin(this.sin_p12 * Math.cos(Ee) + this.cos_p12 * Math.sin(Ee) * cosAz);
	      lon = adjust_lon(this.long0 + Math.asin(Math.sin(Az) * Math.sin(Ee) / Math.cos(psi)));
	      lat = Math.atan((1 - this.es * F * this.sin_p12 / Math.sin(psi)) * Math.tan(psi) / (1 - this.es));
	      p.x = lon;
	      p.y = lat;
	      return p;
	    }
	  }

	}

	var names$26 = ["Azimuthal_Equidistant", "aeqd"];
	var aeqd = {
	  init: init$25,
	  forward: forward$24,
	  inverse: inverse$24,
	  names: names$26
	};

	function init$26() {
	  //double temp;      /* temporary variable    */

	  /* Place parameters in static storage for common use
	      -------------------------------------------------*/
	  this.sin_p14 = Math.sin(this.lat0);
	  this.cos_p14 = Math.cos(this.lat0);
	}

	/* Orthographic forward equations--mapping lat,long to x,y
	    ---------------------------------------------------*/
	function forward$25(p) {
	  var sinphi, cosphi; /* sin and cos value        */
	  var dlon; /* delta longitude value      */
	  var coslon; /* cos of longitude        */
	  var ksp; /* scale factor          */
	  var g, x, y;
	  var lon = p.x;
	  var lat = p.y;
	  /* Forward equations
	      -----------------*/
	  dlon = adjust_lon(lon - this.long0);

	  sinphi = Math.sin(lat);
	  cosphi = Math.cos(lat);

	  coslon = Math.cos(dlon);
	  g = this.sin_p14 * sinphi + this.cos_p14 * cosphi * coslon;
	  ksp = 1;
	  if ((g > 0) || (Math.abs(g) <= EPSLN)) {
	    x = this.a * ksp * cosphi * Math.sin(dlon);
	    y = this.y0 + this.a * ksp * (this.cos_p14 * sinphi - this.sin_p14 * cosphi * coslon);
	  }
	  p.x = x;
	  p.y = y;
	  return p;
	}

	function inverse$25(p) {
	  var rh; /* height above ellipsoid      */
	  var z; /* angle          */
	  var sinz, cosz; /* sin of z and cos of z      */
	  var con;
	  var lon, lat;
	  /* Inverse equations
	      -----------------*/
	  p.x -= this.x0;
	  p.y -= this.y0;
	  rh = Math.sqrt(p.x * p.x + p.y * p.y);
	  z = asinz(rh / this.a);

	  sinz = Math.sin(z);
	  cosz = Math.cos(z);

	  lon = this.long0;
	  if (Math.abs(rh) <= EPSLN) {
	    lat = this.lat0;
	    p.x = lon;
	    p.y = lat;
	    return p;
	  }
	  lat = asinz(cosz * this.sin_p14 + (p.y * sinz * this.cos_p14) / rh);
	  con = Math.abs(this.lat0) - HALF_PI;
	  if (Math.abs(con) <= EPSLN) {
	    if (this.lat0 >= 0) {
	      lon = adjust_lon(this.long0 + Math.atan2(p.x, - p.y));
	    }
	    else {
	      lon = adjust_lon(this.long0 - Math.atan2(-p.x, p.y));
	    }
	    p.x = lon;
	    p.y = lat;
	    return p;
	  }
	  lon = adjust_lon(this.long0 + Math.atan2((p.x * sinz), rh * this.cos_p14 * cosz - p.y * this.sin_p14 * sinz));
	  p.x = lon;
	  p.y = lat;
	  return p;
	}

	var names$27 = ["ortho"];
	var ortho = {
	  init: init$26,
	  forward: forward$25,
	  inverse: inverse$25,
	  names: names$27
	};

	// QSC projection rewritten from the original PROJ4
	// https://github.com/OSGeo/proj.4/blob/master/src/PJ_qsc.c

	/* constants */
	var FACE_ENUM = {
	    FRONT: 1,
	    RIGHT: 2,
	    BACK: 3,
	    LEFT: 4,
	    TOP: 5,
	    BOTTOM: 6
	};

	var AREA_ENUM = {
	    AREA_0: 1,
	    AREA_1: 2,
	    AREA_2: 3,
	    AREA_3: 4
	};

	function init$27() {

	  this.x0 = this.x0 || 0;
	  this.y0 = this.y0 || 0;
	  this.lat0 = this.lat0 || 0;
	  this.long0 = this.long0 || 0;
	  this.lat_ts = this.lat_ts || 0;
	  this.title = this.title || "Quadrilateralized Spherical Cube";

	  /* Determine the cube face from the center of projection. */
	  if (this.lat0 >= HALF_PI - FORTPI / 2.0) {
	    this.face = FACE_ENUM.TOP;
	  } else if (this.lat0 <= -(HALF_PI - FORTPI / 2.0)) {
	    this.face = FACE_ENUM.BOTTOM;
	  } else if (Math.abs(this.long0) <= FORTPI) {
	    this.face = FACE_ENUM.FRONT;
	  } else if (Math.abs(this.long0) <= HALF_PI + FORTPI) {
	    this.face = this.long0 > 0.0 ? FACE_ENUM.RIGHT : FACE_ENUM.LEFT;
	  } else {
	    this.face = FACE_ENUM.BACK;
	  }

	  /* Fill in useful values for the ellipsoid <-> sphere shift
	   * described in [LK12]. */
	  if (this.es !== 0) {
	    this.one_minus_f = 1 - (this.a - this.b) / this.a;
	    this.one_minus_f_squared = this.one_minus_f * this.one_minus_f;
	  }
	}

	// QSC forward equations--mapping lat,long to x,y
	// -----------------------------------------------------------------
	function forward$26(p) {
	  var xy = {x: 0, y: 0};
	  var lat, lon;
	  var theta, phi;
	  var t, mu;
	  /* nu; */
	  var area = {value: 0};

	  // move lon according to projection's lon
	  p.x -= this.long0;

	  /* Convert the geodetic latitude to a geocentric latitude.
	   * This corresponds to the shift from the ellipsoid to the sphere
	   * described in [LK12]. */
	  if (this.es !== 0) {//if (P->es != 0) {
	    lat = Math.atan(this.one_minus_f_squared * Math.tan(p.y));
	  } else {
	    lat = p.y;
	  }

	  /* Convert the input lat, lon into theta, phi as used by QSC.
	   * This depends on the cube face and the area on it.
	   * For the top and bottom face, we can compute theta and phi
	   * directly from phi, lam. For the other faces, we must use
	   * unit sphere cartesian coordinates as an intermediate step. */
	  lon = p.x; //lon = lp.lam;
	  if (this.face === FACE_ENUM.TOP) {
	    phi = HALF_PI - lat;
	    if (lon >= FORTPI && lon <= HALF_PI + FORTPI) {
	      area.value = AREA_ENUM.AREA_0;
	      theta = lon - HALF_PI;
	    } else if (lon > HALF_PI + FORTPI || lon <= -(HALF_PI + FORTPI)) {
	      area.value = AREA_ENUM.AREA_1;
	      theta = (lon > 0.0 ? lon - SPI : lon + SPI);
	    } else if (lon > -(HALF_PI + FORTPI) && lon <= -FORTPI) {
	      area.value = AREA_ENUM.AREA_2;
	      theta = lon + HALF_PI;
	    } else {
	      area.value = AREA_ENUM.AREA_3;
	      theta = lon;
	    }
	  } else if (this.face === FACE_ENUM.BOTTOM) {
	    phi = HALF_PI + lat;
	    if (lon >= FORTPI && lon <= HALF_PI + FORTPI) {
	      area.value = AREA_ENUM.AREA_0;
	      theta = -lon + HALF_PI;
	    } else if (lon < FORTPI && lon >= -FORTPI) {
	      area.value = AREA_ENUM.AREA_1;
	      theta = -lon;
	    } else if (lon < -FORTPI && lon >= -(HALF_PI + FORTPI)) {
	      area.value = AREA_ENUM.AREA_2;
	      theta = -lon - HALF_PI;
	    } else {
	      area.value = AREA_ENUM.AREA_3;
	      theta = (lon > 0.0 ? -lon + SPI : -lon - SPI);
	    }
	  } else {
	    var q, r, s;
	    var sinlat, coslat;
	    var sinlon, coslon;

	    if (this.face === FACE_ENUM.RIGHT) {
	      lon = qsc_shift_lon_origin(lon, +HALF_PI);
	    } else if (this.face === FACE_ENUM.BACK) {
	      lon = qsc_shift_lon_origin(lon, +SPI);
	    } else if (this.face === FACE_ENUM.LEFT) {
	      lon = qsc_shift_lon_origin(lon, -HALF_PI);
	    }
	    sinlat = Math.sin(lat);
	    coslat = Math.cos(lat);
	    sinlon = Math.sin(lon);
	    coslon = Math.cos(lon);
	    q = coslat * coslon;
	    r = coslat * sinlon;
	    s = sinlat;

	    if (this.face === FACE_ENUM.FRONT) {
	      phi = Math.acos(q);
	      theta = qsc_fwd_equat_face_theta(phi, s, r, area);
	    } else if (this.face === FACE_ENUM.RIGHT) {
	      phi = Math.acos(r);
	      theta = qsc_fwd_equat_face_theta(phi, s, -q, area);
	    } else if (this.face === FACE_ENUM.BACK) {
	      phi = Math.acos(-q);
	      theta = qsc_fwd_equat_face_theta(phi, s, -r, area);
	    } else if (this.face === FACE_ENUM.LEFT) {
	      phi = Math.acos(-r);
	      theta = qsc_fwd_equat_face_theta(phi, s, q, area);
	    } else {
	      /* Impossible */
	      phi = theta = 0;
	      area.value = AREA_ENUM.AREA_0;
	    }
	  }

	  /* Compute mu and nu for the area of definition.
	   * For mu, see Eq. (3-21) in [OL76], but note the typos:
	   * compare with Eq. (3-14). For nu, see Eq. (3-38). */
	  mu = Math.atan((12 / SPI) * (theta + Math.acos(Math.sin(theta) * Math.cos(FORTPI)) - HALF_PI));
	  t = Math.sqrt((1 - Math.cos(phi)) / (Math.cos(mu) * Math.cos(mu)) / (1 - Math.cos(Math.atan(1 / Math.cos(theta)))));

	  /* Apply the result to the real area. */
	  if (area.value === AREA_ENUM.AREA_1) {
	    mu += HALF_PI;
	  } else if (area.value === AREA_ENUM.AREA_2) {
	    mu += SPI;
	  } else if (area.value === AREA_ENUM.AREA_3) {
	    mu += 1.5 * SPI;
	  }

	  /* Now compute x, y from mu and nu */
	  xy.x = t * Math.cos(mu);
	  xy.y = t * Math.sin(mu);
	  xy.x = xy.x * this.a + this.x0;
	  xy.y = xy.y * this.a + this.y0;

	  p.x = xy.x;
	  p.y = xy.y;
	  return p;
	}

	// QSC inverse equations--mapping x,y to lat/long
	// -----------------------------------------------------------------
	function inverse$26(p) {
	  var lp = {lam: 0, phi: 0};
	  var mu, nu, cosmu, tannu;
	  var tantheta, theta, cosphi, phi;
	  var t;
	  var area = {value: 0};

	  /* de-offset */
	  p.x = (p.x - this.x0) / this.a;
	  p.y = (p.y - this.y0) / this.a;

	  /* Convert the input x, y to the mu and nu angles as used by QSC.
	   * This depends on the area of the cube face. */
	  nu = Math.atan(Math.sqrt(p.x * p.x + p.y * p.y));
	  mu = Math.atan2(p.y, p.x);
	  if (p.x >= 0.0 && p.x >= Math.abs(p.y)) {
	    area.value = AREA_ENUM.AREA_0;
	  } else if (p.y >= 0.0 && p.y >= Math.abs(p.x)) {
	    area.value = AREA_ENUM.AREA_1;
	    mu -= HALF_PI;
	  } else if (p.x < 0.0 && -p.x >= Math.abs(p.y)) {
	    area.value = AREA_ENUM.AREA_2;
	    mu = (mu < 0.0 ? mu + SPI : mu - SPI);
	  } else {
	    area.value = AREA_ENUM.AREA_3;
	    mu += HALF_PI;
	  }

	  /* Compute phi and theta for the area of definition.
	   * The inverse projection is not described in the original paper, but some
	   * good hints can be found here (as of 2011-12-14):
	   * http://fits.gsfc.nasa.gov/fitsbits/saf.93/saf.9302
	   * (search for "Message-Id: <9302181759.AA25477 at fits.cv.nrao.edu>") */
	  t = (SPI / 12) * Math.tan(mu);
	  tantheta = Math.sin(t) / (Math.cos(t) - (1 / Math.sqrt(2)));
	  theta = Math.atan(tantheta);
	  cosmu = Math.cos(mu);
	  tannu = Math.tan(nu);
	  cosphi = 1 - cosmu * cosmu * tannu * tannu * (1 - Math.cos(Math.atan(1 / Math.cos(theta))));
	  if (cosphi < -1) {
	    cosphi = -1;
	  } else if (cosphi > +1) {
	    cosphi = +1;
	  }

	  /* Apply the result to the real area on the cube face.
	   * For the top and bottom face, we can compute phi and lam directly.
	   * For the other faces, we must use unit sphere cartesian coordinates
	   * as an intermediate step. */
	  if (this.face === FACE_ENUM.TOP) {
	    phi = Math.acos(cosphi);
	    lp.phi = HALF_PI - phi;
	    if (area.value === AREA_ENUM.AREA_0) {
	      lp.lam = theta + HALF_PI;
	    } else if (area.value === AREA_ENUM.AREA_1) {
	      lp.lam = (theta < 0.0 ? theta + SPI : theta - SPI);
	    } else if (area.value === AREA_ENUM.AREA_2) {
	      lp.lam = theta - HALF_PI;
	    } else /* area.value == AREA_ENUM.AREA_3 */ {
	      lp.lam = theta;
	    }
	  } else if (this.face === FACE_ENUM.BOTTOM) {
	    phi = Math.acos(cosphi);
	    lp.phi = phi - HALF_PI;
	    if (area.value === AREA_ENUM.AREA_0) {
	      lp.lam = -theta + HALF_PI;
	    } else if (area.value === AREA_ENUM.AREA_1) {
	      lp.lam = -theta;
	    } else if (area.value === AREA_ENUM.AREA_2) {
	      lp.lam = -theta - HALF_PI;
	    } else /* area.value == AREA_ENUM.AREA_3 */ {
	      lp.lam = (theta < 0.0 ? -theta - SPI : -theta + SPI);
	    }
	  } else {
	    /* Compute phi and lam via cartesian unit sphere coordinates. */
	    var q, r, s;
	    q = cosphi;
	    t = q * q;
	    if (t >= 1) {
	      s = 0;
	    } else {
	      s = Math.sqrt(1 - t) * Math.sin(theta);
	    }
	    t += s * s;
	    if (t >= 1) {
	      r = 0;
	    } else {
	      r = Math.sqrt(1 - t);
	    }
	    /* Rotate q,r,s into the correct area. */
	    if (area.value === AREA_ENUM.AREA_1) {
	      t = r;
	      r = -s;
	      s = t;
	    } else if (area.value === AREA_ENUM.AREA_2) {
	      r = -r;
	      s = -s;
	    } else if (area.value === AREA_ENUM.AREA_3) {
	      t = r;
	      r = s;
	      s = -t;
	    }
	    /* Rotate q,r,s into the correct cube face. */
	    if (this.face === FACE_ENUM.RIGHT) {
	      t = q;
	      q = -r;
	      r = t;
	    } else if (this.face === FACE_ENUM.BACK) {
	      q = -q;
	      r = -r;
	    } else if (this.face === FACE_ENUM.LEFT) {
	      t = q;
	      q = r;
	      r = -t;
	    }
	    /* Now compute phi and lam from the unit sphere coordinates. */
	    lp.phi = Math.acos(-s) - HALF_PI;
	    lp.lam = Math.atan2(r, q);
	    if (this.face === FACE_ENUM.RIGHT) {
	      lp.lam = qsc_shift_lon_origin(lp.lam, -HALF_PI);
	    } else if (this.face === FACE_ENUM.BACK) {
	      lp.lam = qsc_shift_lon_origin(lp.lam, -SPI);
	    } else if (this.face === FACE_ENUM.LEFT) {
	      lp.lam = qsc_shift_lon_origin(lp.lam, +HALF_PI);
	    }
	  }

	  /* Apply the shift from the sphere to the ellipsoid as described
	   * in [LK12]. */
	  if (this.es !== 0) {
	    var invert_sign;
	    var tanphi, xa;
	    invert_sign = (lp.phi < 0 ? 1 : 0);
	    tanphi = Math.tan(lp.phi);
	    xa = this.b / Math.sqrt(tanphi * tanphi + this.one_minus_f_squared);
	    lp.phi = Math.atan(Math.sqrt(this.a * this.a - xa * xa) / (this.one_minus_f * xa));
	    if (invert_sign) {
	      lp.phi = -lp.phi;
	    }
	  }

	  lp.lam += this.long0;
	  p.x = lp.lam;
	  p.y = lp.phi;
	  return p;
	}

	/* Helper function for forward projection: compute the theta angle
	 * and determine the area number. */
	function qsc_fwd_equat_face_theta(phi, y, x, area) {
	  var theta;
	  if (phi < EPSLN) {
	    area.value = AREA_ENUM.AREA_0;
	    theta = 0.0;
	  } else {
	    theta = Math.atan2(y, x);
	    if (Math.abs(theta) <= FORTPI) {
	      area.value = AREA_ENUM.AREA_0;
	    } else if (theta > FORTPI && theta <= HALF_PI + FORTPI) {
	      area.value = AREA_ENUM.AREA_1;
	      theta -= HALF_PI;
	    } else if (theta > HALF_PI + FORTPI || theta <= -(HALF_PI + FORTPI)) {
	      area.value = AREA_ENUM.AREA_2;
	      theta = (theta >= 0.0 ? theta - SPI : theta + SPI);
	    } else {
	      area.value = AREA_ENUM.AREA_3;
	      theta += HALF_PI;
	    }
	  }
	  return theta;
	}

	/* Helper function: shift the longitude. */
	function qsc_shift_lon_origin(lon, offset) {
	  var slon = lon + offset;
	  if (slon < -SPI) {
	    slon += TWO_PI;
	  } else if (slon > +SPI) {
	    slon -= TWO_PI;
	  }
	  return slon;
	}

	var names$28 = ["Quadrilateralized Spherical Cube", "Quadrilateralized_Spherical_Cube", "qsc"];
	var qsc = {
	  init: init$27,
	  forward: forward$26,
	  inverse: inverse$26,
	  names: names$28
	};

	var includedProjections = function(proj4){
	  proj4.Proj.projections.add(tmerc);
	  proj4.Proj.projections.add(etmerc);
	  proj4.Proj.projections.add(utm);
	  proj4.Proj.projections.add(sterea);
	  proj4.Proj.projections.add(stere);
	  proj4.Proj.projections.add(somerc);
	  proj4.Proj.projections.add(omerc);
	  proj4.Proj.projections.add(lcc);
	  proj4.Proj.projections.add(krovak);
	  proj4.Proj.projections.add(cass);
	  proj4.Proj.projections.add(laea);
	  proj4.Proj.projections.add(aea);
	  proj4.Proj.projections.add(gnom);
	  proj4.Proj.projections.add(cea);
	  proj4.Proj.projections.add(eqc);
	  proj4.Proj.projections.add(poly);
	  proj4.Proj.projections.add(nzmg);
	  proj4.Proj.projections.add(mill);
	  proj4.Proj.projections.add(sinu);
	  proj4.Proj.projections.add(moll);
	  proj4.Proj.projections.add(eqdc);
	  proj4.Proj.projections.add(vandg);
	  proj4.Proj.projections.add(aeqd);
	  proj4.Proj.projections.add(ortho);
	  proj4.Proj.projections.add(qsc);
	};

	proj4$1.defaultDatum = 'WGS84'; //default datum
	proj4$1.Proj = Projection$1;
	proj4$1.WGS84 = new proj4$1.Proj('WGS84');
	proj4$1.Point = Point;
	proj4$1.toPoint = toPoint;
	proj4$1.defs = defs;
	proj4$1.transform = transform;
	proj4$1.mgrs = mgrs;
	proj4$1.version = version;
	includedProjections(proj4$1);

	return proj4$1;

})));
